\f
;;;; coercions
-(defknown %single-float (real) single-float (movable foldable flushable))
-(defknown %double-float (real) double-float (movable foldable flushable))
+(defknown %single-float (real) single-float
+ (movable foldable))
+(defknown %double-float (real) double-float
+ (movable foldable))
-(deftransform float ((n &optional f) (* &optional single-float) *)
+(deftransform float ((n f) (* single-float) *)
'(%single-float n))
(deftransform float ((n f) (* double-float) *)
'(%double-float n))
+(deftransform float ((n) *)
+ '(if (floatp n)
+ n
+ (%single-float n)))
+
(deftransform %single-float ((n) (single-float) *)
'n)
;;; RANDOM
(macrolet ((frob (fun type)
- `(deftransform random ((num &optional state)
- (,type &optional *) *)
- "Use inline float operations."
- '(,fun num (or state *random-state*)))))
+ `(deftransform random ((num &optional state)
+ (,type &optional *) *)
+ "Use inline float operations."
+ '(,fun num (or state *random-state*)))))
(frob %random-single-float single-float)
(frob %random-double-float double-float))
-;;; Mersenne Twister RNG
-;;;
-;;; FIXME: It's unpleasant to have RANDOM functionality scattered
-;;; through the code this way. It would be nice to move this into the
-;;; same file as the other RANDOM definitions.
+;;; Return an expression to generate an integer of N-BITS many random
+;;; bits, using the minimal number of random chunks possible.
+(defun generate-random-expr-for-power-of-2 (n-bits state)
+ (declare (type (integer 1 #.sb!vm:n-word-bits) n-bits))
+ (multiple-value-bind (n-chunk-bits chunk-expr)
+ (cond ((<= n-bits n-random-chunk-bits)
+ (values n-random-chunk-bits `(random-chunk ,state)))
+ ((<= n-bits (* 2 n-random-chunk-bits))
+ (values (* 2 n-random-chunk-bits) `(big-random-chunk ,state)))
+ (t
+ (error "Unexpectedly small N-RANDOM-CHUNK-BITS")))
+ (if (< n-bits n-chunk-bits)
+ `(logand ,(1- (ash 1 n-bits)) ,chunk-expr)
+ chunk-expr)))
+
+;;; This transform for compile-time constant word-sized integers
+;;; generates an accept-reject loop to achieve equidistribution of the
+;;; returned values. Several optimizations are done: If NUM is a power
+;;; of two no loop is needed. If the random chunk size is half the word
+;;; size only one chunk is used where sufficient. For values of NUM
+;;; where it is possible and results in faster code, the rejection
+;;; probability is reduced by accepting all values below the largest
+;;; multiple of the limit that fits into one or two chunks and and doing
+;;; a division to get the random value into the desired range.
(deftransform random ((num &optional state)
- ((integer 1 #.(expt 2 32)) &optional *))
- ;; FIXME: I almost conditionalized this as #!+sb-doc. Find some way
- ;; of automatically finding #!+sb-doc in proximity to DEFTRANSFORM
- ;; to let me scan for places that I made this mistake and didn't
- ;; catch myself.
- "use inline (UNSIGNED-BYTE 32) operations"
- (let ((num-high (numeric-type-high (continuation-type num))))
- (when (null num-high)
- (give-up-ir1-transform))
- (cond ((constant-continuation-p num)
- ;; Check the worst case sum absolute error for the random number
- ;; expectations.
- (let ((rem (rem (expt 2 32) num-high)))
- (unless (< (/ (* 2 rem (- num-high rem)) num-high (expt 2 32))
- (expt 2 (- sb!kernel::random-integer-extra-bits)))
- (give-up-ir1-transform
- "The random number expectations are inaccurate."))
- (if (= num-high (expt 2 32))
- '(random-chunk (or state *random-state*))
- #!-x86 '(rem (random-chunk (or state *random-state*)) num)
- #!+x86
- ;; Use multiplication, which is faster.
- '(values (sb!bignum::%multiply
- (random-chunk (or state *random-state*))
- num)))))
- ((> num-high random-fixnum-max)
- (give-up-ir1-transform
- "The range is too large to ensure an accurate result."))
- #!+x86
- ((< num-high (expt 2 32))
- '(values (sb!bignum::%multiply (random-chunk (or state
- *random-state*))
- num)))
- (t
- '(rem (random-chunk (or state *random-state*)) num)))))
+ ((constant-arg (integer 1 #.(expt 2 sb!vm:n-word-bits)))
+ &optional *)
+ *
+ :policy (and (> speed compilation-speed)
+ (> speed space)))
+ "optimize to inlined RANDOM-CHUNK operations"
+ (let ((num (lvar-value num)))
+ (if (= num 1)
+ 0
+ (flet ((chunk-n-bits-and-expr (n-bits)
+ (cond ((<= n-bits n-random-chunk-bits)
+ (values n-random-chunk-bits
+ '(random-chunk (or state *random-state*))))
+ ((<= n-bits (* 2 n-random-chunk-bits))
+ (values (* 2 n-random-chunk-bits)
+ '(big-random-chunk (or state *random-state*))))
+ (t
+ (error "Unexpectedly small N-RANDOM-CHUNK-BITS")))))
+ (if (zerop (logand num (1- num)))
+ ;; NUM is a power of 2.
+ (let ((n-bits (integer-length (1- num))))
+ (multiple-value-bind (n-chunk-bits chunk-expr)
+ (chunk-n-bits-and-expr n-bits)
+ (if (< n-bits n-chunk-bits)
+ `(logand ,(1- (ash 1 n-bits)) ,chunk-expr)
+ chunk-expr)))
+ ;; Generate an accept-reject loop.
+ (let ((n-bits (integer-length num)))
+ (multiple-value-bind (n-chunk-bits chunk-expr)
+ (chunk-n-bits-and-expr n-bits)
+ (if (or (> (* num 3) (expt 2 n-chunk-bits))
+ (logbitp (- n-bits 2) num))
+ ;; Division can't help as the quotient is below 3,
+ ;; or is too costly as the rejection probability
+ ;; without it is already small (namely at most 1/4
+ ;; with the given test, which is experimentally a
+ ;; reasonable threshold and cheap to test for).
+ `(loop
+ (let ((bits ,(generate-random-expr-for-power-of-2
+ n-bits '(or state *random-state*))))
+ (when (< bits num)
+ (return bits))))
+ (let ((d (truncate (expt 2 n-chunk-bits) num)))
+ `(loop
+ (let ((bits ,chunk-expr))
+ (when (< bits ,(* num d))
+ (return (values (truncate bits ,d)))))))))))))))
+
\f
;;;; float accessors
(defknown make-single-float ((signed-byte 32)) single-float
- (movable foldable flushable))
+ (movable flushable))
(defknown make-double-float ((signed-byte 32) (unsigned-byte 32)) double-float
- (movable foldable flushable))
+ (movable flushable))
+
+#-sb-xc-host
+(deftransform make-single-float ((bits)
+ ((signed-byte 32)))
+ "Conditional constant folding"
+ (unless (constant-lvar-p bits)
+ (give-up-ir1-transform))
+ (let* ((bits (lvar-value bits))
+ (float (make-single-float bits)))
+ (when (float-nan-p float)
+ (give-up-ir1-transform))
+ float))
+
+#-sb-xc-host
+(deftransform make-double-float ((hi lo)
+ ((signed-byte 32) (unsigned-byte 32)))
+ "Conditional constant folding"
+ (unless (and (constant-lvar-p hi)
+ (constant-lvar-p lo))
+ (give-up-ir1-transform))
+ (let* ((hi (lvar-value hi))
+ (lo (lvar-value lo))
+ (float (make-double-float hi lo)))
+ (when (float-nan-p float)
+ (give-up-ir1-transform))
+ float))
(defknown single-float-bits (single-float) (signed-byte 32)
(movable foldable flushable))
(movable foldable flushable))
(deftransform float-sign ((float &optional float2)
- (single-float &optional single-float) *)
+ (single-float &optional single-float) *)
(if float2
(let ((temp (gensym)))
- `(let ((,temp (abs float2)))
- (if (minusp (single-float-bits float)) (- ,temp) ,temp)))
+ `(let ((,temp (abs float2)))
+ (if (minusp (single-float-bits float)) (- ,temp) ,temp)))
'(if (minusp (single-float-bits float)) -1f0 1f0)))
(deftransform float-sign ((float &optional float2)
- (double-float &optional double-float) *)
+ (double-float &optional double-float) *)
(if float2
(let ((temp (gensym)))
- `(let ((,temp (abs float2)))
- (if (minusp (double-float-high-bits float)) (- ,temp) ,temp)))
+ `(let ((,temp (abs float2)))
+ (if (minusp (double-float-high-bits float)) (- ,temp) ,temp)))
'(if (minusp (double-float-high-bits float)) -1d0 1d0)))
\f
;;;; DECODE-FLOAT, INTEGER-DECODE-FLOAT, and SCALE-FLOAT
(values double-float-significand double-float-int-exponent (integer -1 1))
(movable foldable flushable))
-(defknown scale-single-float (single-float fixnum) single-float
+(defknown scale-single-float (single-float integer) single-float
(movable foldable flushable))
-(defknown scale-double-float (double-float fixnum) double-float
+(defknown scale-double-float (double-float integer) double-float
(movable foldable flushable))
(deftransform decode-float ((x) (single-float) *)
(deftransform scale-float ((f ex) (single-float *) *)
(if (and #!+x86 t #!-x86 nil
- (csubtypep (continuation-type ex)
- (specifier-type '(signed-byte 32))))
+ (csubtypep (lvar-type ex)
+ (specifier-type '(signed-byte 32))))
'(coerce (%scalbn (coerce f 'double-float) ex) 'single-float)
'(scale-single-float f ex)))
(deftransform scale-float ((f ex) (double-float *) *)
(if (and #!+x86 t #!-x86 nil
- (csubtypep (continuation-type ex)
- (specifier-type '(signed-byte 32))))
+ (csubtypep (lvar-type ex)
+ (specifier-type '(signed-byte 32))))
'(%scalbn f ex)
'(scale-double-float f ex)))
(defun scale-float-derive-type-aux (f ex same-arg)
(declare (ignore same-arg))
(flet ((scale-bound (x n)
- ;; We need to be a bit careful here and catch any overflows
- ;; that might occur. We can ignore underflows which become
- ;; zeros.
- (set-bound
- (handler-case
- (scale-float (type-bound-number x) n)
- (floating-point-overflow ()
- nil))
- (consp x))))
+ ;; We need to be a bit careful here and catch any overflows
+ ;; that might occur. We can ignore underflows which become
+ ;; zeros.
+ (set-bound
+ (handler-case
+ (scale-float (type-bound-number x) n)
+ (floating-point-overflow ()
+ nil))
+ (consp x))))
(when (and (numeric-type-p f) (numeric-type-p ex))
(let ((f-lo (numeric-type-low f))
- (f-hi (numeric-type-high f))
- (ex-lo (numeric-type-low ex))
- (ex-hi (numeric-type-high ex))
- (new-lo nil)
- (new-hi nil))
- (when (and f-hi ex-hi)
- (setf new-hi (scale-bound f-hi ex-hi)))
- (when (and f-lo ex-lo)
- (setf new-lo (scale-bound f-lo ex-lo)))
- (make-numeric-type :class (numeric-type-class f)
- :format (numeric-type-format f)
- :complexp :real
- :low new-lo
- :high new-hi)))))
+ (f-hi (numeric-type-high f))
+ (ex-lo (numeric-type-low ex))
+ (ex-hi (numeric-type-high ex))
+ (new-lo nil)
+ (new-hi nil))
+ (when f-hi
+ (if (< (float-sign (type-bound-number f-hi)) 0.0)
+ (when ex-lo
+ (setf new-hi (scale-bound f-hi ex-lo)))
+ (when ex-hi
+ (setf new-hi (scale-bound f-hi ex-hi)))))
+ (when f-lo
+ (if (< (float-sign (type-bound-number f-lo)) 0.0)
+ (when ex-hi
+ (setf new-lo (scale-bound f-lo ex-hi)))
+ (when ex-lo
+ (setf new-lo (scale-bound f-lo ex-lo)))))
+ (make-numeric-type :class (numeric-type-class f)
+ :format (numeric-type-format f)
+ :complexp :real
+ :low new-lo
+ :high new-hi)))))
(defoptimizer (scale-single-float derive-type) ((f ex))
(two-arg-derive-type f ex #'scale-float-derive-type-aux
- #'scale-single-float t))
+ #'scale-single-float t))
(defoptimizer (scale-double-float derive-type) ((f ex))
(two-arg-derive-type f ex #'scale-float-derive-type-aux
- #'scale-double-float t))
+ #'scale-double-float t))
;;; DEFOPTIMIZERs for %SINGLE-FLOAT and %DOUBLE-FLOAT. This makes the
;;; FLOAT function return the correct ranges if the input has some
;;; defined range. Quite useful if we want to convert some type of
;;; bounded integer into a float.
(macrolet
- ((frob (fun type)
+ ((frob (fun type most-negative most-positive)
(let ((aux-name (symbolicate fun "-DERIVE-TYPE-AUX")))
- `(progn
- (defun ,aux-name (num)
- ;; When converting a number to a float, the limits are
- ;; the same.
- (let* ((lo (bound-func (lambda (x)
- (coerce x ',type))
- (numeric-type-low num)))
- (hi (bound-func (lambda (x)
- (coerce x ',type))
- (numeric-type-high num))))
- (specifier-type `(,',type ,(or lo '*) ,(or hi '*)))))
-
- (defoptimizer (,fun derive-type) ((num))
- (one-arg-derive-type num #',aux-name #',fun))))))
- (frob %single-float single-float)
- (frob %double-float double-float))
-) ; PROGN
+ `(progn
+ (defun ,aux-name (num)
+ ;; When converting a number to a float, the limits are
+ ;; the same.
+ (let* ((lo (bound-func (lambda (x)
+ (if (< x ,most-negative)
+ ,most-negative
+ (coerce x ',type)))
+ (numeric-type-low num)
+ nil))
+ (hi (bound-func (lambda (x)
+ (if (< ,most-positive x )
+ ,most-positive
+ (coerce x ',type)))
+ (numeric-type-high num)
+ nil)))
+ (specifier-type `(,',type ,(or lo '*) ,(or hi '*)))))
+
+ (defoptimizer (,fun derive-type) ((num))
+ (handler-case
+ (one-arg-derive-type num #',aux-name #',fun)
+ (type-error ()
+ nil)))))))
+ (frob %single-float single-float
+ most-negative-single-float most-positive-single-float)
+ (frob %double-float double-float
+ most-negative-double-float most-positive-double-float))
+) ; PROGN
\f
;;;; float contagion
+(defun safe-ctype-for-single-coercion-p (x)
+ ;; See comment in SAFE-SINGLE-COERCION-P -- this deals with the same
+ ;; problem, but in the context of evaluated and compiled (+ <int> <single>)
+ ;; giving different result if we fail to check for this.
+ (or (not (csubtypep x (specifier-type 'integer)))
+ #!+x86
+ (csubtypep x (specifier-type `(integer ,most-negative-exactly-single-float-fixnum
+ ,most-positive-exactly-single-float-fixnum)))
+ #!-x86
+ (csubtypep x (specifier-type 'fixnum))))
+
;;; Do some stuff to recognize when the loser is doing mixed float and
;;; rational arithmetic, or different float types, and fix it up. If
;;; we don't, he won't even get so much as an efficiency note.
(deftransform float-contagion-arg1 ((x y) * * :defun-only t :node node)
- `(,(continuation-fun-name (basic-combination-fun node))
- (float x y) y))
+ (if (or (not (types-equal-or-intersect (lvar-type y) (specifier-type 'single-float)))
+ (safe-ctype-for-single-coercion-p (lvar-type x)))
+ `(,(lvar-fun-name (basic-combination-fun node))
+ (float x y) y)
+ (give-up-ir1-transform)))
(deftransform float-contagion-arg2 ((x y) * * :defun-only t :node node)
- `(,(continuation-fun-name (basic-combination-fun node))
- x (float y x)))
+ (if (or (not (types-equal-or-intersect (lvar-type x) (specifier-type 'single-float)))
+ (safe-ctype-for-single-coercion-p (lvar-type y)))
+ `(,(lvar-fun-name (basic-combination-fun node))
+ x (float y x))
+ (give-up-ir1-transform)))
(dolist (x '(+ * / -))
(%deftransform x '(function (rational float) *) #'float-contagion-arg1)
(dolist (x '(= < > + * / -))
(%deftransform x '(function (single-float double-float) *)
- #'float-contagion-arg1)
+ #'float-contagion-arg1)
(%deftransform x '(function (double-float single-float) *)
- #'float-contagion-arg2))
+ #'float-contagion-arg2))
+
+(macrolet ((def (type &rest args)
+ `(deftransform * ((x y) (,type (constant-arg (member ,@args))) *
+ ;; Beware the SNaN!
+ :policy (zerop float-accuracy))
+ "optimize multiplication by one"
+ (let ((y (lvar-value y)))
+ (if (minusp y)
+ '(%negate x)
+ 'x)))))
+ (def single-float 1.0 -1.0)
+ (def double-float 1.0d0 -1.0d0))
+
+;;; Return the reciprocal of X if it can be represented exactly, NIL otherwise.
+(defun maybe-exact-reciprocal (x)
+ (unless (zerop x)
+ (handler-case
+ (multiple-value-bind (significand exponent sign)
+ (integer-decode-float x)
+ ;; only powers of 2 can be inverted exactly
+ (unless (zerop (logand significand (1- significand)))
+ (return-from maybe-exact-reciprocal nil))
+ (let ((expected (/ sign significand (expt 2 exponent)))
+ (reciprocal (/ x)))
+ (multiple-value-bind (significand exponent sign)
+ (integer-decode-float reciprocal)
+ ;; Denorms can't be inverted safely.
+ (and (eql expected (* sign significand (expt 2 exponent)))
+ reciprocal))))
+ (error () (return-from maybe-exact-reciprocal nil)))))
+
+;;; Replace constant division by multiplication with exact reciprocal,
+;;; if one exists.
+(macrolet ((def (type)
+ `(deftransform / ((x y) (,type (constant-arg ,type)) *
+ :node node)
+ "convert to multiplication by reciprocal"
+ (let ((n (lvar-value y)))
+ (if (policy node (zerop float-accuracy))
+ `(* x ,(/ n))
+ (let ((r (maybe-exact-reciprocal n)))
+ (if r
+ `(* x ,r)
+ (give-up-ir1-transform
+ "~S does not have an exact reciprocal"
+ n))))))))
+ (def single-float)
+ (def double-float))
+
+;;; Optimize addition and subtraction of zero
+(macrolet ((def (op type &rest args)
+ `(deftransform ,op ((x y) (,type (constant-arg (member ,@args))) *
+ ;; Beware the SNaN!
+ :policy (zerop float-accuracy))
+ 'x)))
+ ;; No signed zeros, thanks.
+ (def + single-float 0 0.0)
+ (def - single-float 0 0.0)
+ (def + double-float 0 0.0 0.0d0)
+ (def - double-float 0 0.0 0.0d0))
+
+;;; On most platforms (+ x x) is faster than (* x 2)
+(macrolet ((def (type &rest args)
+ `(deftransform * ((x y) (,type (constant-arg (member ,@args))))
+ '(+ x x))))
+ (def single-float 2 2.0)
+ (def double-float 2 2.0 2.0d0))
;;; Prevent ZEROP, PLUSP, and MINUSP from losing horribly. We can't in
;;; general float rational args to comparison, since Common Lisp
;;; do it for any rational that has a precise representation as a
;;; float (such as 0).
(macrolet ((frob (op)
- `(deftransform ,op ((x y) (float rational) *)
- "open-code FLOAT to RATIONAL comparison"
- (unless (constant-continuation-p y)
- (give-up-ir1-transform
- "The RATIONAL value isn't known at compile time."))
- (let ((val (continuation-value y)))
- (unless (eql (rational (float val)) val)
- (give-up-ir1-transform
- "~S doesn't have a precise float representation."
- val)))
- `(,',op x (float y x)))))
+ `(deftransform ,op ((x y) (float rational) *)
+ "open-code FLOAT to RATIONAL comparison"
+ (unless (constant-lvar-p y)
+ (give-up-ir1-transform
+ "The RATIONAL value isn't known at compile time."))
+ (let ((val (lvar-value y)))
+ (unless (eql (rational (float val)) val)
+ (give-up-ir1-transform
+ "~S doesn't have a precise float representation."
+ val)))
+ `(,',op x (float y x)))))
(frob <)
(frob >)
(frob =))
;;; appropriate domain.
#+sb-xc-host ; (See CROSS-FLOAT-INFINITY-KLUDGE.)
(dolist (stuff '((asin (real -1.0 1.0))
- (acos (real -1.0 1.0))
- (acosh (real 1.0))
- (atanh (real -1.0 1.0))
- (sqrt (real 0.0))))
+ (acos (real -1.0 1.0))
+ (acosh (real 1.0))
+ (atanh (real -1.0 1.0))
+ (sqrt (real 0.0))))
(destructuring-bind (name type) stuff
(let ((type (specifier-type type)))
(setf (fun-info-derive-type (fun-info-or-lose name))
- (lambda (call)
- (declare (type combination call))
- (when (csubtypep (continuation-type
- (first (combination-args call)))
- type)
- (specifier-type 'float)))))))
+ (lambda (call)
+ (declare (type combination call))
+ (when (csubtypep (lvar-type
+ (first (combination-args call)))
+ type)
+ (specifier-type 'float)))))))
#+sb-xc-host ; (See CROSS-FLOAT-INFINITY-KLUDGE.)
(defoptimizer (log derive-type) ((x &optional y))
- (when (and (csubtypep (continuation-type x)
- (specifier-type '(real 0.0)))
- (or (null y)
- (csubtypep (continuation-type y)
- (specifier-type '(real 0.0)))))
+ (when (and (csubtypep (lvar-type x)
+ (specifier-type '(real 0.0)))
+ (or (null y)
+ (csubtypep (lvar-type y)
+ (specifier-type '(real 0.0)))))
(specifier-type 'float)))
\f
;;;; irrational transforms
(defknown (%tan %sinh %asinh %atanh %log %logb %log10 %tan-quick)
- (double-float) double-float
+ (double-float) double-float
(movable foldable flushable))
(defknown (%sin %cos %tanh %sin-quick %cos-quick)
(defknown (%asin %atan)
(double-float)
(double-float #.(coerce (- (/ pi 2)) 'double-float)
- #.(coerce (/ pi 2) 'double-float))
+ #.(coerce (/ pi 2) 'double-float))
(movable foldable flushable))
(defknown (%acos)
(defknown (%atan2)
(double-float double-float)
(double-float #.(coerce (- pi) 'double-float)
- #.(coerce pi 'double-float))
+ #.(coerce pi 'double-float))
(movable foldable flushable))
(defknown (%scalb)
(declare (ignorable prim-quick))
`(progn
(deftransform ,name ((x) (single-float) *)
- #!+x86 (cond ((csubtypep (continuation-type x)
+ #!+x86 (cond ((csubtypep (lvar-type x)
(specifier-type '(single-float
- (#.(- (expt 2f0 64)))
- (#.(expt 2f0 64)))))
+ (#.(- (expt 2f0 63)))
+ (#.(expt 2f0 63)))))
`(coerce (,',prim-quick (coerce x 'double-float))
'single-float))
(t
- (compiler-note
+ (compiler-notify
"unable to avoid inline argument range check~@
- because the argument range (~S) was not within 2^64"
- (type-specifier (continuation-type x)))
+ because the argument range (~S) was not within 2^63"
+ (type-specifier (lvar-type x)))
`(coerce (,',prim (coerce x 'double-float)) 'single-float)))
#!-x86 `(coerce (,',prim (coerce x 'double-float)) 'single-float))
(deftransform ,name ((x) (double-float) *)
- #!+x86 (cond ((csubtypep (continuation-type x)
+ #!+x86 (cond ((csubtypep (lvar-type x)
(specifier-type '(double-float
- (#.(- (expt 2d0 64)))
- (#.(expt 2d0 64)))))
+ (#.(- (expt 2d0 63)))
+ (#.(expt 2d0 63)))))
`(,',prim-quick x))
(t
- (compiler-note
+ (compiler-notify
"unable to avoid inline argument range check~@
- because the argument range (~S) was not within 2^64"
- (type-specifier (continuation-type x)))
+ because the argument range (~S) was not within 2^63"
+ (type-specifier (lvar-type x)))
`(,',prim x)))
#!-x86 `(,',prim x)))))
(def sin %sin %sin-quick)
(deftransform abs ((x) ((complex single-float)) single-float)
'(coerce (%hypot (coerce (realpart x) 'double-float)
- (coerce (imagpart x) 'double-float))
- 'single-float))
+ (coerce (imagpart x) 'double-float))
+ 'single-float))
(deftransform phase ((x) ((complex double-float)) double-float)
'(%atan2 (imagpart x) (realpart x)))
(deftransform phase ((x) ((complex single-float)) single-float)
'(coerce (%atan2 (coerce (imagpart x) 'double-float)
- (coerce (realpart x) 'double-float))
- 'single-float))
+ (coerce (realpart x) 'double-float))
+ 'single-float))
(deftransform phase ((x) ((float)) float)
'(if (minusp (float-sign x))
(defun coerce-numeric-bound (bound type)
(when bound
(if (consp bound)
- (list (coerce (car bound) type))
- (coerce bound type))))
+ (list (coerce (car bound) type))
+ (coerce bound type))))
#-sb-xc-host ; (See CROSS-FLOAT-INFINITY-KLUDGE.)
(progn
(defun complex-float-type (arg)
(declare (type numeric-type arg))
(let* ((format (case (numeric-type-class arg)
- ((integer rational) 'single-float)
- (t (numeric-type-format arg))))
- (float-type (or format 'float)))
+ ((integer rational) 'single-float)
+ (t (numeric-type-format arg))))
+ (float-type (or format 'float)))
(specifier-type `(complex ,float-type))))
;;; Compute a specifier like '(OR FLOAT (COMPLEX FLOAT)), except float
(defun float-or-complex-float-type (arg &optional lo hi)
(declare (type numeric-type arg))
(let* ((format (case (numeric-type-class arg)
- ((integer rational) 'single-float)
- (t (numeric-type-format arg))))
- (float-type (or format 'float))
- (lo (coerce-numeric-bound lo float-type))
- (hi (coerce-numeric-bound hi float-type)))
+ ((integer rational) 'single-float)
+ (t (numeric-type-format arg))))
+ (float-type (or format 'float))
+ (lo (coerce-numeric-bound lo float-type))
+ (hi (coerce-numeric-bound hi float-type)))
(specifier-type `(or (,float-type ,(or lo '*) ,(or hi '*))
- (complex ,float-type)))))
+ (complex ,float-type)))))
+
+) ; PROGN
-;;; Test whether the numeric-type ARG is within in domain specified by
+(eval-when (:compile-toplevel :execute)
+ ;; So the problem with this hack is that it's actually broken. If
+ ;; the host does not have long floats, then setting *R-D-F-F* to
+ ;; LONG-FLOAT doesn't actually buy us anything. FIXME.
+ (setf *read-default-float-format*
+ #!+long-float 'long-float #!-long-float 'double-float))
+;;; Test whether the numeric-type ARG is within the domain specified by
;;; DOMAIN-LOW and DOMAIN-HIGH, consider negative and positive zero to
-;;; be distinct as for the :NEGATIVE-ZERO-IS-NOT-ZERO feature. With
-;;; the :NEGATIVE-ZERO-IS-NOT-ZERO feature this could be handled by
-;;; the numeric subtype code in type.lisp.
+;;; be distinct.
+#-sb-xc-host ; (See CROSS-FLOAT-INFINITY-KLUDGE.)
(defun domain-subtypep (arg domain-low domain-high)
(declare (type numeric-type arg)
- (type (or real null) domain-low domain-high))
+ (type (or real null) domain-low domain-high))
(let* ((arg-lo (numeric-type-low arg))
- (arg-lo-val (type-bound-number arg-lo))
- (arg-hi (numeric-type-high arg))
- (arg-hi-val (type-bound-number arg-hi)))
+ (arg-lo-val (type-bound-number arg-lo))
+ (arg-hi (numeric-type-high arg))
+ (arg-hi-val (type-bound-number arg-hi)))
;; Check that the ARG bounds are correctly canonicalized.
(when (and arg-lo (floatp arg-lo-val) (zerop arg-lo-val) (consp arg-lo)
- (minusp (float-sign arg-lo-val)))
- (compiler-note "float zero bound ~S not correctly canonicalized?" arg-lo)
- (setq arg-lo '(0l0) arg-lo-val 0l0))
+ (minusp (float-sign arg-lo-val)))
+ (compiler-notify "float zero bound ~S not correctly canonicalized?" arg-lo)
+ (setq arg-lo 0e0 arg-lo-val arg-lo))
(when (and arg-hi (zerop arg-hi-val) (floatp arg-hi-val) (consp arg-hi)
- (plusp (float-sign arg-hi-val)))
- (compiler-note "float zero bound ~S not correctly canonicalized?" arg-hi)
- (setq arg-hi '(-0l0) arg-hi-val -0l0))
- (and (or (null domain-low)
- (and arg-lo (>= arg-lo-val domain-low)
- (not (and (zerop domain-low) (floatp domain-low)
- (plusp (float-sign domain-low))
- (zerop arg-lo-val) (floatp arg-lo-val)
- (if (consp arg-lo)
- (plusp (float-sign arg-lo-val))
- (minusp (float-sign arg-lo-val)))))))
- (or (null domain-high)
- (and arg-hi (<= arg-hi-val domain-high)
- (not (and (zerop domain-high) (floatp domain-high)
- (minusp (float-sign domain-high))
- (zerop arg-hi-val) (floatp arg-hi-val)
- (if (consp arg-hi)
- (minusp (float-sign arg-hi-val))
- (plusp (float-sign arg-hi-val))))))))))
+ (plusp (float-sign arg-hi-val)))
+ (compiler-notify "float zero bound ~S not correctly canonicalized?" arg-hi)
+ (setq arg-hi (ecase *read-default-float-format*
+ (double-float (load-time-value (make-unportable-float :double-float-negative-zero)))
+ #!+long-float
+ (long-float (load-time-value (make-unportable-float :long-float-negative-zero))))
+ arg-hi-val arg-hi))
+ (flet ((fp-neg-zero-p (f) ; Is F -0.0?
+ (and (floatp f) (zerop f) (minusp (float-sign f))))
+ (fp-pos-zero-p (f) ; Is F +0.0?
+ (and (floatp f) (zerop f) (plusp (float-sign f)))))
+ (and (or (null domain-low)
+ (and arg-lo (>= arg-lo-val domain-low)
+ (not (and (fp-pos-zero-p domain-low)
+ (fp-neg-zero-p arg-lo)))))
+ (or (null domain-high)
+ (and arg-hi (<= arg-hi-val domain-high)
+ (not (and (fp-neg-zero-p domain-high)
+ (fp-pos-zero-p arg-hi)))))))))
+(eval-when (:compile-toplevel :execute)
+ (setf *read-default-float-format* 'single-float))
+
+#-sb-xc-host ; (See CROSS-FLOAT-INFINITY-KLUDGE.)
+(progn
;;; Handle monotonic functions of a single variable whose domain is
-;;; possibly part of the real line. ARG is the variable, FCN is the
+;;; possibly part of the real line. ARG is the variable, FUN is the
;;; function, and DOMAIN is a specifier that gives the (real) domain
;;; of the function. If ARG is a subset of the DOMAIN, we compute the
;;; bounds directly. Otherwise, we compute the bounds for the
;;; result, which occurs for the parts of ARG not in the DOMAIN.
;;;
;;; Negative and positive zero are considered distinct within
-;;; DOMAIN-LOW and DOMAIN-HIGH, as for the :negative-zero-is-not-zero
-;;; feature.
+;;; DOMAIN-LOW and DOMAIN-HIGH.
;;;
;;; DEFAULT-LOW and DEFAULT-HIGH are the lower and upper bounds if we
-;;; can't compute the bounds using FCN.
-(defun elfun-derive-type-simple (arg fcn domain-low domain-high
- default-low default-high
- &optional (increasingp t))
+;;; can't compute the bounds using FUN.
+(defun elfun-derive-type-simple (arg fun domain-low domain-high
+ default-low default-high
+ &optional (increasingp t))
(declare (type (or null real) domain-low domain-high))
(etypecase arg
(numeric-type
(cond ((eq (numeric-type-complexp arg) :complex)
- (make-numeric-type :class (numeric-type-class arg)
- :format (numeric-type-format arg)
- :complexp :complex))
- ((numeric-type-real-p arg)
- ;; The argument is real, so let's find the intersection
- ;; between the argument and the domain of the function.
- ;; We compute the bounds on the intersection, and for
- ;; everything else, we return a complex number of the
- ;; appropriate type.
- (multiple-value-bind (intersection difference)
- (interval-intersection/difference (numeric-type->interval arg)
- (make-interval
- :low domain-low
- :high domain-high))
- (cond
- (intersection
- ;; Process the intersection.
- (let* ((low (interval-low intersection))
- (high (interval-high intersection))
- (res-lo (or (bound-func fcn (if increasingp low high))
- default-low))
- (res-hi (or (bound-func fcn (if increasingp high low))
- default-high))
- (format (case (numeric-type-class arg)
- ((integer rational) 'single-float)
- (t (numeric-type-format arg))))
- (bound-type (or format 'float))
- (result-type
- (make-numeric-type
- :class 'float
- :format format
- :low (coerce-numeric-bound res-lo bound-type)
- :high (coerce-numeric-bound res-hi bound-type))))
- ;; If the ARG is a subset of the domain, we don't
- ;; have to worry about the difference, because that
- ;; can't occur.
- (if (or (null difference)
- ;; Check whether the arg is within the domain.
- (domain-subtypep arg domain-low domain-high))
- result-type
- (list result-type
- (specifier-type `(complex ,bound-type))))))
- (t
- ;; No intersection so the result must be purely complex.
- (complex-float-type arg)))))
- (t
- (float-or-complex-float-type arg default-low default-high))))))
+ (complex-float-type arg))
+ ((numeric-type-real-p arg)
+ ;; The argument is real, so let's find the intersection
+ ;; between the argument and the domain of the function.
+ ;; We compute the bounds on the intersection, and for
+ ;; everything else, we return a complex number of the
+ ;; appropriate type.
+ (multiple-value-bind (intersection difference)
+ (interval-intersection/difference (numeric-type->interval arg)
+ (make-interval
+ :low domain-low
+ :high domain-high))
+ (cond
+ (intersection
+ ;; Process the intersection.
+ (let* ((low (interval-low intersection))
+ (high (interval-high intersection))
+ (res-lo (or (bound-func fun (if increasingp low high) nil)
+ default-low))
+ (res-hi (or (bound-func fun (if increasingp high low) nil)
+ default-high))
+ (format (case (numeric-type-class arg)
+ ((integer rational) 'single-float)
+ (t (numeric-type-format arg))))
+ (bound-type (or format 'float))
+ (result-type
+ (make-numeric-type
+ :class 'float
+ :format format
+ :low (coerce-numeric-bound res-lo bound-type)
+ :high (coerce-numeric-bound res-hi bound-type))))
+ ;; If the ARG is a subset of the domain, we don't
+ ;; have to worry about the difference, because that
+ ;; can't occur.
+ (if (or (null difference)
+ ;; Check whether the arg is within the domain.
+ (domain-subtypep arg domain-low domain-high))
+ result-type
+ (list result-type
+ (specifier-type `(complex ,bound-type))))))
+ (t
+ ;; No intersection so the result must be purely complex.
+ (complex-float-type arg)))))
+ (t
+ (float-or-complex-float-type arg default-low default-high))))))
(macrolet
((frob (name domain-low domain-high def-low-bnd def-high-bnd
- &key (increasingp t))
+ &key (increasingp t))
(let ((num (gensym)))
- `(defoptimizer (,name derive-type) ((,num))
- (one-arg-derive-type
- ,num
- (lambda (arg)
- (elfun-derive-type-simple arg #',name
- ,domain-low ,domain-high
- ,def-low-bnd ,def-high-bnd
- ,increasingp))
- #',name)))))
+ `(defoptimizer (,name derive-type) ((,num))
+ (one-arg-derive-type
+ ,num
+ (lambda (arg)
+ (elfun-derive-type-simple arg #',name
+ ,domain-low ,domain-high
+ ,def-low-bnd ,def-high-bnd
+ ,increasingp))
+ #',name)))))
;; These functions are easy because they are defined for the whole
;; real line.
(frob exp nil nil 0 nil)
(frob atanh -1d0 1d0 -1 1)
;; Kahan says that (sqrt -0.0) is -0.0, so use a specifier that
;; includes -0.0.
- (frob sqrt -0d0 nil 0 nil))
+ (frob sqrt (load-time-value (make-unportable-float :double-float-negative-zero)) nil 0 nil))
;;; Compute bounds for (expt x y). This should be easy since (expt x
;;; y) = (exp (* y (log x))). However, computations done this way
;;; have too much roundoff. Thus we have to do it the hard way.
(defun safe-expt (x y)
(handler-case
- (expt x y)
+ (when (< (abs y) 10000)
+ (expt x y))
(error ()
nil)))
;;; Handle the case when x >= 1.
(defun interval-expt-> (x y)
(case (sb!c::interval-range-info y 0d0)
- ('+
+ (+
;; Y is positive and log X >= 0. The range of exp(y * log(x)) is
;; obviously non-negative. We just have to be careful for
;; infinite bounds (given by nil).
(let ((lo (safe-expt (type-bound-number (sb!c::interval-low x))
- (type-bound-number (sb!c::interval-low y))))
- (hi (safe-expt (type-bound-number (sb!c::interval-high x))
- (type-bound-number (sb!c::interval-high y)))))
+ (type-bound-number (sb!c::interval-low y))))
+ (hi (safe-expt (type-bound-number (sb!c::interval-high x))
+ (type-bound-number (sb!c::interval-high y)))))
(list (sb!c::make-interval :low (or lo 1) :high hi))))
- ('-
+ (-
;; Y is negative and log x >= 0. The range of exp(y * log(x)) is
;; obviously [0, 1]. However, underflow (nil) means 0 is the
;; result.
(let ((lo (safe-expt (type-bound-number (sb!c::interval-high x))
- (type-bound-number (sb!c::interval-low y))))
- (hi (safe-expt (type-bound-number (sb!c::interval-low x))
- (type-bound-number (sb!c::interval-high y)))))
+ (type-bound-number (sb!c::interval-low y))))
+ (hi (safe-expt (type-bound-number (sb!c::interval-low x))
+ (type-bound-number (sb!c::interval-high y)))))
(list (sb!c::make-interval :low (or lo 0) :high (or hi 1)))))
(t
;; Split the interval in half.
(destructuring-bind (y- y+)
- (sb!c::interval-split 0 y t)
+ (sb!c::interval-split 0 y t)
(list (interval-expt-> x y-)
- (interval-expt-> x y+))))))
+ (interval-expt-> x y+))))))
;;; Handle the case when x <= 1
(defun interval-expt-< (x y)
(case (sb!c::interval-range-info x 0d0)
- ('+
+ (+
;; The case of 0 <= x <= 1 is easy
(case (sb!c::interval-range-info y)
- ('+
- ;; Y is positive and log X <= 0. The range of exp(y * log(x)) is
- ;; obviously [0, 1]. We just have to be careful for infinite bounds
- ;; (given by nil).
- (let ((lo (safe-expt (type-bound-number (sb!c::interval-low x))
- (type-bound-number (sb!c::interval-high y))))
- (hi (safe-expt (type-bound-number (sb!c::interval-high x))
- (type-bound-number (sb!c::interval-low y)))))
- (list (sb!c::make-interval :low (or lo 0) :high (or hi 1)))))
- ('-
- ;; Y is negative and log x <= 0. The range of exp(y * log(x)) is
- ;; obviously [1, inf].
- (let ((hi (safe-expt (type-bound-number (sb!c::interval-low x))
- (type-bound-number (sb!c::interval-low y))))
- (lo (safe-expt (type-bound-number (sb!c::interval-high x))
- (type-bound-number (sb!c::interval-high y)))))
- (list (sb!c::make-interval :low (or lo 1) :high hi))))
+ (+
+ ;; Y is positive and log X <= 0. The range of exp(y * log(x)) is
+ ;; obviously [0, 1]. We just have to be careful for infinite bounds
+ ;; (given by nil).
+ (let ((lo (safe-expt (type-bound-number (sb!c::interval-low x))
+ (type-bound-number (sb!c::interval-high y))))
+ (hi (safe-expt (type-bound-number (sb!c::interval-high x))
+ (type-bound-number (sb!c::interval-low y)))))
+ (list (sb!c::make-interval :low (or lo 0) :high (or hi 1)))))
+ (-
+ ;; Y is negative and log x <= 0. The range of exp(y * log(x)) is
+ ;; obviously [1, inf].
+ (let ((hi (safe-expt (type-bound-number (sb!c::interval-low x))
+ (type-bound-number (sb!c::interval-low y))))
+ (lo (safe-expt (type-bound-number (sb!c::interval-high x))
+ (type-bound-number (sb!c::interval-high y)))))
+ (list (sb!c::make-interval :low (or lo 1) :high hi))))
(t
- ;; Split the interval in half
- (destructuring-bind (y- y+)
- (sb!c::interval-split 0 y t)
- (list (interval-expt-< x y-)
- (interval-expt-< x y+))))))
- ('-
+ ;; Split the interval in half
+ (destructuring-bind (y- y+)
+ (sb!c::interval-split 0 y t)
+ (list (interval-expt-< x y-)
+ (interval-expt-< x y+))))))
+ (-
;; The case where x <= 0. Y MUST be an INTEGER for this to work!
;; The calling function must insure this! For now we'll just
;; return the appropriate unbounded float type.
(list (sb!c::make-interval :low nil :high nil)))
(t
(destructuring-bind (neg pos)
- (interval-split 0 x t t)
+ (interval-split 0 x t t)
(list (interval-expt-< neg y)
- (interval-expt-< pos y))))))
+ (interval-expt-< pos y))))))
;;; Compute bounds for (expt x y).
(defun interval-expt (x y)
(case (interval-range-info x 1)
- ('+
+ (+
;; X >= 1
- (interval-expt-> x y))
- ('-
+ (interval-expt-> x y))
+ (-
;; X <= 1
(interval-expt-< x y))
(t
(destructuring-bind (left right)
- (interval-split 1 x t t)
+ (interval-split 1 x t t)
(list (interval-expt left y)
- (interval-expt right y))))))
+ (interval-expt right y))))))
(defun fixup-interval-expt (bnd x-int y-int x-type y-type)
(declare (ignore x-int))
;; Figure out what the return type should be, given the argument
;; types and bounds and the result type and bounds.
(cond ((csubtypep x-type (specifier-type 'integer))
- ;; an integer to some power
- (case (numeric-type-class y-type)
- (integer
- ;; Positive integer to an integer power is either an
- ;; integer or a rational.
- (let ((lo (or (interval-low bnd) '*))
- (hi (or (interval-high bnd) '*)))
- (if (and (interval-low y-int)
- (>= (type-bound-number (interval-low y-int)) 0))
- (specifier-type `(integer ,lo ,hi))
- (specifier-type `(rational ,lo ,hi)))))
- (rational
- ;; Positive integer to rational power is either a rational
- ;; or a single-float.
- (let* ((lo (interval-low bnd))
- (hi (interval-high bnd))
- (int-lo (if lo
- (floor (type-bound-number lo))
- '*))
- (int-hi (if hi
- (ceiling (type-bound-number hi))
- '*))
- (f-lo (if lo
- (bound-func #'float lo)
- '*))
- (f-hi (if hi
- (bound-func #'float hi)
- '*)))
- (specifier-type `(or (rational ,int-lo ,int-hi)
- (single-float ,f-lo, f-hi)))))
- (float
- ;; A positive integer to a float power is a float.
- (modified-numeric-type y-type
- :low (interval-low bnd)
- :high (interval-high bnd)))
- (t
- ;; A positive integer to a number is a number (for now).
- (specifier-type 'number))))
- ((csubtypep x-type (specifier-type 'rational))
- ;; a rational to some power
- (case (numeric-type-class y-type)
- (integer
- ;; A positive rational to an integer power is always a rational.
- (specifier-type `(rational ,(or (interval-low bnd) '*)
- ,(or (interval-high bnd) '*))))
- (rational
- ;; A positive rational to rational power is either a rational
- ;; or a single-float.
- (let* ((lo (interval-low bnd))
- (hi (interval-high bnd))
- (int-lo (if lo
- (floor (type-bound-number lo))
- '*))
- (int-hi (if hi
- (ceiling (type-bound-number hi))
- '*))
- (f-lo (if lo
- (bound-func #'float lo)
- '*))
- (f-hi (if hi
- (bound-func #'float hi)
- '*)))
- (specifier-type `(or (rational ,int-lo ,int-hi)
- (single-float ,f-lo, f-hi)))))
- (float
- ;; A positive rational to a float power is a float.
- (modified-numeric-type y-type
- :low (interval-low bnd)
- :high (interval-high bnd)))
- (t
- ;; A positive rational to a number is a number (for now).
- (specifier-type 'number))))
- ((csubtypep x-type (specifier-type 'float))
- ;; a float to some power
- (case (numeric-type-class y-type)
- ((or integer rational)
- ;; A positive float to an integer or rational power is
- ;; always a float.
- (make-numeric-type
- :class 'float
- :format (numeric-type-format x-type)
- :low (interval-low bnd)
- :high (interval-high bnd)))
- (float
- ;; A positive float to a float power is a float of the
- ;; higher type.
- (make-numeric-type
- :class 'float
- :format (float-format-max (numeric-type-format x-type)
- (numeric-type-format y-type))
- :low (interval-low bnd)
- :high (interval-high bnd)))
- (t
- ;; A positive float to a number is a number (for now)
- (specifier-type 'number))))
- (t
- ;; A number to some power is a number.
- (specifier-type 'number))))
+ ;; an integer to some power
+ (case (numeric-type-class y-type)
+ (integer
+ ;; Positive integer to an integer power is either an
+ ;; integer or a rational.
+ (let ((lo (or (interval-low bnd) '*))
+ (hi (or (interval-high bnd) '*)))
+ (if (and (interval-low y-int)
+ (>= (type-bound-number (interval-low y-int)) 0))
+ (specifier-type `(integer ,lo ,hi))
+ (specifier-type `(rational ,lo ,hi)))))
+ (rational
+ ;; Positive integer to rational power is either a rational
+ ;; or a single-float.
+ (let* ((lo (interval-low bnd))
+ (hi (interval-high bnd))
+ (int-lo (if lo
+ (floor (type-bound-number lo))
+ '*))
+ (int-hi (if hi
+ (ceiling (type-bound-number hi))
+ '*))
+ (f-lo (or (bound-func #'float lo nil)
+ '*))
+ (f-hi (or (bound-func #'float hi nil)
+ '*)))
+ (specifier-type `(or (rational ,int-lo ,int-hi)
+ (single-float ,f-lo, f-hi)))))
+ (float
+ ;; A positive integer to a float power is a float.
+ (let ((format (numeric-type-format y-type)))
+ (aver format)
+ (modified-numeric-type
+ y-type
+ :low (coerce-numeric-bound (interval-low bnd) format)
+ :high (coerce-numeric-bound (interval-high bnd) format))))
+ (t
+ ;; A positive integer to a number is a number (for now).
+ (specifier-type 'number))))
+ ((csubtypep x-type (specifier-type 'rational))
+ ;; a rational to some power
+ (case (numeric-type-class y-type)
+ (integer
+ ;; A positive rational to an integer power is always a rational.
+ (specifier-type `(rational ,(or (interval-low bnd) '*)
+ ,(or (interval-high bnd) '*))))
+ (rational
+ ;; A positive rational to rational power is either a rational
+ ;; or a single-float.
+ (let* ((lo (interval-low bnd))
+ (hi (interval-high bnd))
+ (int-lo (if lo
+ (floor (type-bound-number lo))
+ '*))
+ (int-hi (if hi
+ (ceiling (type-bound-number hi))
+ '*))
+ (f-lo (or (bound-func #'float lo nil)
+ '*))
+ (f-hi (or (bound-func #'float hi nil)
+ '*)))
+ (specifier-type `(or (rational ,int-lo ,int-hi)
+ (single-float ,f-lo, f-hi)))))
+ (float
+ ;; A positive rational to a float power is a float.
+ (let ((format (numeric-type-format y-type)))
+ (aver format)
+ (modified-numeric-type
+ y-type
+ :low (coerce-numeric-bound (interval-low bnd) format)
+ :high (coerce-numeric-bound (interval-high bnd) format))))
+ (t
+ ;; A positive rational to a number is a number (for now).
+ (specifier-type 'number))))
+ ((csubtypep x-type (specifier-type 'float))
+ ;; a float to some power
+ (case (numeric-type-class y-type)
+ ((or integer rational)
+ ;; A positive float to an integer or rational power is
+ ;; always a float.
+ (let ((format (numeric-type-format x-type)))
+ (aver format)
+ (make-numeric-type
+ :class 'float
+ :format format
+ :low (coerce-numeric-bound (interval-low bnd) format)
+ :high (coerce-numeric-bound (interval-high bnd) format))))
+ (float
+ ;; A positive float to a float power is a float of the
+ ;; higher type.
+ (let ((format (float-format-max (numeric-type-format x-type)
+ (numeric-type-format y-type))))
+ (aver format)
+ (make-numeric-type
+ :class 'float
+ :format format
+ :low (coerce-numeric-bound (interval-low bnd) format)
+ :high (coerce-numeric-bound (interval-high bnd) format))))
+ (t
+ ;; A positive float to a number is a number (for now)
+ (specifier-type 'number))))
+ (t
+ ;; A number to some power is a number.
+ (specifier-type 'number))))
(defun merged-interval-expt (x y)
(let* ((x-int (numeric-type->interval x))
- (y-int (numeric-type->interval y)))
+ (y-int (numeric-type->interval y)))
(mapcar (lambda (type)
- (fixup-interval-expt type x-int y-int x y))
- (flatten-list (interval-expt x-int y-int)))))
+ (fixup-interval-expt type x-int y-int x y))
+ (flatten-list (interval-expt x-int y-int)))))
(defun expt-derive-type-aux (x y same-arg)
(declare (ignore same-arg))
(cond ((or (not (numeric-type-real-p x))
- (not (numeric-type-real-p y)))
- ;; Use numeric contagion if either is not real.
- (numeric-contagion x y))
- ((csubtypep y (specifier-type 'integer))
- ;; A real raised to an integer power is well-defined.
- (merged-interval-expt x y))
- (t
- ;; A real raised to a non-integral power can be a float or a
- ;; complex number.
- (cond ((or (csubtypep x (specifier-type '(rational 0)))
- (csubtypep x (specifier-type '(float (0d0)))))
- ;; But a positive real to any power is well-defined.
- (merged-interval-expt x y))
- (t
- ;; a real to some power. The result could be a real
- ;; or a complex.
- (float-or-complex-float-type (numeric-contagion x y)))))))
+ (not (numeric-type-real-p y)))
+ ;; Use numeric contagion if either is not real.
+ (numeric-contagion x y))
+ ((csubtypep y (specifier-type 'integer))
+ ;; A real raised to an integer power is well-defined.
+ (merged-interval-expt x y))
+ ;; A real raised to a non-integral power can be a float or a
+ ;; complex number.
+ ((or (csubtypep x (specifier-type '(rational 0)))
+ (csubtypep x (specifier-type '(float (0d0)))))
+ ;; But a positive real to any power is well-defined.
+ (merged-interval-expt x y))
+ ((and (csubtypep x (specifier-type 'rational))
+ (csubtypep y (specifier-type 'rational)))
+ ;; A rational to the power of a rational could be a rational
+ ;; or a possibly-complex single float
+ (specifier-type '(or rational single-float (complex single-float))))
+ (t
+ ;; a real to some power. The result could be a real or a
+ ;; complex.
+ (float-or-complex-float-type (numeric-contagion x y)))))
(defoptimizer (expt derive-type) ((x y))
(two-arg-derive-type x y #'expt-derive-type-aux #'expt))
(defun log-derive-type-aux-2 (x y same-arg)
(let ((log-x (log-derive-type-aux-1 x))
- (log-y (log-derive-type-aux-1 y))
- (accumulated-list nil))
+ (log-y (log-derive-type-aux-1 y))
+ (accumulated-list nil))
;; LOG-X or LOG-Y might be union types. We need to run through
;; the union types ourselves because /-DERIVE-TYPE-AUX doesn't.
(dolist (x-type (prepare-arg-for-derive-type log-x))
(dolist (y-type (prepare-arg-for-derive-type log-y))
- (push (/-derive-type-aux x-type y-type same-arg) accumulated-list)))
+ (push (/-derive-type-aux x-type y-type same-arg) accumulated-list)))
(apply #'type-union (flatten-list accumulated-list))))
(defoptimizer (log derive-type) ((x &optional y))
;; The hard case with two args. We just return the max bounds.
(let ((result-type (numeric-contagion y x)))
(cond ((and (numeric-type-real-p x)
- (numeric-type-real-p y))
- (let* (;; FIXME: This expression for FORMAT seems to
- ;; appear multiple times, and should be factored out.
- (format (case (numeric-type-class result-type)
- ((integer rational) 'single-float)
- (t (numeric-type-format result-type))))
- (bound-format (or format 'float)))
- (make-numeric-type :class 'float
- :format format
- :complexp :real
- :low (coerce (- pi) bound-format)
- :high (coerce pi bound-format))))
- (t
- ;; The result is a float or a complex number
- (float-or-complex-float-type result-type)))))
+ (numeric-type-real-p y))
+ (let* (;; FIXME: This expression for FORMAT seems to
+ ;; appear multiple times, and should be factored out.
+ (format (case (numeric-type-class result-type)
+ ((integer rational) 'single-float)
+ (t (numeric-type-format result-type))))
+ (bound-format (or format 'float)))
+ (make-numeric-type :class 'float
+ :format format
+ :complexp :real
+ :low (coerce (- pi) bound-format)
+ :high (coerce pi bound-format))))
+ (t
+ ;; The result is a float or a complex number
+ (float-or-complex-float-type result-type)))))
(defoptimizer (atan derive-type) ((y &optional x))
(if x
(defun phase-derive-type-aux (arg)
(let* ((format (case (numeric-type-class arg)
- ((integer rational) 'single-float)
- (t (numeric-type-format arg))))
- (bound-type (or format 'float)))
+ ((integer rational) 'single-float)
+ (t (numeric-type-format arg))))
+ (bound-type (or format 'float)))
(cond ((numeric-type-real-p arg)
- (case (interval-range-info (numeric-type->interval arg) 0.0)
- ('+
- ;; The number is positive, so the phase is 0.
- (make-numeric-type :class 'float
- :format format
- :complexp :real
- :low (coerce 0 bound-type)
- :high (coerce 0 bound-type)))
- ('-
- ;; The number is always negative, so the phase is pi.
- (make-numeric-type :class 'float
- :format format
- :complexp :real
- :low (coerce pi bound-type)
- :high (coerce pi bound-type)))
- (t
- ;; We can't tell. The result is 0 or pi. Use a union
- ;; type for this.
- (list
- (make-numeric-type :class 'float
- :format format
- :complexp :real
- :low (coerce 0 bound-type)
- :high (coerce 0 bound-type))
- (make-numeric-type :class 'float
- :format format
- :complexp :real
- :low (coerce pi bound-type)
- :high (coerce pi bound-type))))))
- (t
- ;; We have a complex number. The answer is the range -pi
- ;; to pi. (-pi is included because we have -0.)
- (make-numeric-type :class 'float
- :format format
- :complexp :real
- :low (coerce (- pi) bound-type)
- :high (coerce pi bound-type))))))
+ (case (interval-range-info (numeric-type->interval arg) 0.0)
+ (+
+ ;; The number is positive, so the phase is 0.
+ (make-numeric-type :class 'float
+ :format format
+ :complexp :real
+ :low (coerce 0 bound-type)
+ :high (coerce 0 bound-type)))
+ (-
+ ;; The number is always negative, so the phase is pi.
+ (make-numeric-type :class 'float
+ :format format
+ :complexp :real
+ :low (coerce pi bound-type)
+ :high (coerce pi bound-type)))
+ (t
+ ;; We can't tell. The result is 0 or pi. Use a union
+ ;; type for this.
+ (list
+ (make-numeric-type :class 'float
+ :format format
+ :complexp :real
+ :low (coerce 0 bound-type)
+ :high (coerce 0 bound-type))
+ (make-numeric-type :class 'float
+ :format format
+ :complexp :real
+ :low (coerce pi bound-type)
+ :high (coerce pi bound-type))))))
+ (t
+ ;; We have a complex number. The answer is the range -pi
+ ;; to pi. (-pi is included because we have -0.)
+ (make-numeric-type :class 'float
+ :format format
+ :complexp :real
+ :low (coerce (- pi) bound-type)
+ :high (coerce pi bound-type))))))
(defoptimizer (phase derive-type) ((num))
(one-arg-derive-type num #'phase-derive-type-aux #'phase))
;;; should help a lot in optimized code.
(defun realpart-derive-type-aux (type)
(let ((class (numeric-type-class type))
- (format (numeric-type-format type)))
+ (format (numeric-type-format type)))
(cond ((numeric-type-real-p type)
- ;; The realpart of a real has the same type and range as
- ;; the input.
- (make-numeric-type :class class
- :format format
- :complexp :real
- :low (numeric-type-low type)
- :high (numeric-type-high type)))
- (t
- ;; We have a complex number. The result has the same type
- ;; as the real part, except that it's real, not complex,
- ;; obviously.
- (make-numeric-type :class class
- :format format
- :complexp :real
- :low (numeric-type-low type)
- :high (numeric-type-high type))))))
-#-sb-xc-host ; (See CROSS-FLOAT-INFINITY-KLUDGE.)
+ ;; The realpart of a real has the same type and range as
+ ;; the input.
+ (make-numeric-type :class class
+ :format format
+ :complexp :real
+ :low (numeric-type-low type)
+ :high (numeric-type-high type)))
+ (t
+ ;; We have a complex number. The result has the same type
+ ;; as the real part, except that it's real, not complex,
+ ;; obviously.
+ (make-numeric-type :class class
+ :format format
+ :complexp :real
+ :low (numeric-type-low type)
+ :high (numeric-type-high type))))))
+
(defoptimizer (realpart derive-type) ((num))
(one-arg-derive-type num #'realpart-derive-type-aux #'realpart))
+
(defun imagpart-derive-type-aux (type)
(let ((class (numeric-type-class type))
- (format (numeric-type-format type)))
+ (format (numeric-type-format type)))
(cond ((numeric-type-real-p type)
- ;; The imagpart of a real has the same type as the input,
- ;; except that it's zero.
- (let ((bound-format (or format class 'real)))
- (make-numeric-type :class class
- :format format
- :complexp :real
- :low (coerce 0 bound-format)
- :high (coerce 0 bound-format))))
- (t
- ;; We have a complex number. The result has the same type as
- ;; the imaginary part, except that it's real, not complex,
- ;; obviously.
- (make-numeric-type :class class
- :format format
- :complexp :real
- :low (numeric-type-low type)
- :high (numeric-type-high type))))))
-#-sb-xc-host ; (See CROSS-FLOAT-INFINITY-KLUDGE.)
+ ;; The imagpart of a real has the same type as the input,
+ ;; except that it's zero.
+ (let ((bound-format (or format class 'real)))
+ (make-numeric-type :class class
+ :format format
+ :complexp :real
+ :low (coerce 0 bound-format)
+ :high (coerce 0 bound-format))))
+ (t
+ ;; We have a complex number. The result has the same type as
+ ;; the imaginary part, except that it's real, not complex,
+ ;; obviously.
+ (make-numeric-type :class class
+ :format format
+ :complexp :real
+ :low (numeric-type-low type)
+ :high (numeric-type-high type))))))
+
(defoptimizer (imagpart derive-type) ((num))
(one-arg-derive-type num #'imagpart-derive-type-aux #'imagpart))
(defun complex-derive-type-aux-1 (re-type)
(if (numeric-type-p re-type)
(make-numeric-type :class (numeric-type-class re-type)
- :format (numeric-type-format re-type)
- :complexp (if (csubtypep re-type
- (specifier-type 'rational))
- :real
- :complex)
- :low (numeric-type-low re-type)
- :high (numeric-type-high re-type))
+ :format (numeric-type-format re-type)
+ :complexp (if (csubtypep re-type
+ (specifier-type 'rational))
+ :real
+ :complex)
+ :low (numeric-type-low re-type)
+ :high (numeric-type-high re-type))
(specifier-type 'complex)))
(defun complex-derive-type-aux-2 (re-type im-type same-arg)
(declare (ignore same-arg))
(if (and (numeric-type-p re-type)
- (numeric-type-p im-type))
+ (numeric-type-p im-type))
;; Need to check to make sure numeric-contagion returns the
;; right type for what we want here.
;; arguments are rational, we make it a union type of (or
;; rational (complex rational)).
(let* ((element-type (numeric-contagion re-type im-type))
- (rat-result-p (csubtypep element-type
- (specifier-type 'rational))))
- (if rat-result-p
- (type-union element-type
- (specifier-type
- `(complex ,(numeric-type-class element-type))))
- (make-numeric-type :class (numeric-type-class element-type)
- :format (numeric-type-format element-type)
- :complexp (if rat-result-p
- :real
- :complex))))
+ (rat-result-p (csubtypep element-type
+ (specifier-type 'rational))))
+ (if rat-result-p
+ (type-union element-type
+ (specifier-type
+ `(complex ,(numeric-type-class element-type))))
+ (make-numeric-type :class (numeric-type-class element-type)
+ :format (numeric-type-format element-type)
+ :complexp (if rat-result-p
+ :real
+ :complex))))
(specifier-type 'complex)))
#-sb-xc-host ; (See CROSS-FLOAT-INFINITY-KLUDGE.)
;;; Define some transforms for complex operations. We do this in lieu
;;; of complex operation VOPs.
(macrolet ((frob (type)
- `(progn
- ;; negation
- (deftransform %negate ((z) ((complex ,type)) *)
- '(complex (%negate (realpart z)) (%negate (imagpart z))))
- ;; complex addition and subtraction
- (deftransform + ((w z) ((complex ,type) (complex ,type)) *)
- '(complex (+ (realpart w) (realpart z))
- (+ (imagpart w) (imagpart z))))
- (deftransform - ((w z) ((complex ,type) (complex ,type)) *)
- '(complex (- (realpart w) (realpart z))
- (- (imagpart w) (imagpart z))))
- ;; Add and subtract a complex and a real.
- (deftransform + ((w z) ((complex ,type) real) *)
- '(complex (+ (realpart w) z) (imagpart w)))
- (deftransform + ((z w) (real (complex ,type)) *)
- '(complex (+ (realpart w) z) (imagpart w)))
- ;; Add and subtract a real and a complex number.
- (deftransform - ((w z) ((complex ,type) real) *)
- '(complex (- (realpart w) z) (imagpart w)))
- (deftransform - ((z w) (real (complex ,type)) *)
- '(complex (- z (realpart w)) (- (imagpart w))))
- ;; Multiply and divide two complex numbers.
- (deftransform * ((x y) ((complex ,type) (complex ,type)) *)
- '(let* ((rx (realpart x))
- (ix (imagpart x))
- (ry (realpart y))
- (iy (imagpart y)))
- (complex (- (* rx ry) (* ix iy))
- (+ (* rx iy) (* ix ry)))))
- (deftransform / ((x y) ((complex ,type) (complex ,type)) *)
- '(let* ((rx (realpart x))
- (ix (imagpart x))
- (ry (realpart y))
- (iy (imagpart y)))
- (if (> (abs ry) (abs iy))
- (let* ((r (/ iy ry))
- (dn (* ry (+ 1 (* r r)))))
- (complex (/ (+ rx (* ix r)) dn)
- (/ (- ix (* rx r)) dn)))
- (let* ((r (/ ry iy))
- (dn (* iy (+ 1 (* r r)))))
- (complex (/ (+ (* rx r) ix) dn)
- (/ (- (* ix r) rx) dn))))))
- ;; Multiply a complex by a real or vice versa.
- (deftransform * ((w z) ((complex ,type) real) *)
- '(complex (* (realpart w) z) (* (imagpart w) z)))
- (deftransform * ((z w) (real (complex ,type)) *)
- '(complex (* (realpart w) z) (* (imagpart w) z)))
- ;; Divide a complex by a real.
- (deftransform / ((w z) ((complex ,type) real) *)
- '(complex (/ (realpart w) z) (/ (imagpart w) z)))
- ;; conjugate of complex number
- (deftransform conjugate ((z) ((complex ,type)) *)
- '(complex (realpart z) (- (imagpart z))))
- ;; CIS
- (deftransform cis ((z) ((,type)) *)
- '(complex (cos z) (sin z)))
- ;; comparison
- (deftransform = ((w z) ((complex ,type) (complex ,type)) *)
- '(and (= (realpart w) (realpart z))
- (= (imagpart w) (imagpart z))))
- (deftransform = ((w z) ((complex ,type) real) *)
- '(and (= (realpart w) z) (zerop (imagpart w))))
- (deftransform = ((w z) (real (complex ,type)) *)
- '(and (= (realpart z) w) (zerop (imagpart z)))))))
+ `(progn
+ (deftransform complex ((r) (,type))
+ '(complex r ,(coerce 0 type)))
+ (deftransform complex ((r i) (,type (and real (not ,type))))
+ '(complex r (truly-the ,type (coerce i ',type))))
+ (deftransform complex ((r i) ((and real (not ,type)) ,type))
+ '(complex (truly-the ,type (coerce r ',type)) i))
+ ;; negation
+ #!-complex-float-vops
+ (deftransform %negate ((z) ((complex ,type)) *)
+ '(complex (%negate (realpart z)) (%negate (imagpart z))))
+ ;; complex addition and subtraction
+ #!-complex-float-vops
+ (deftransform + ((w z) ((complex ,type) (complex ,type)) *)
+ '(complex (+ (realpart w) (realpart z))
+ (+ (imagpart w) (imagpart z))))
+ #!-complex-float-vops
+ (deftransform - ((w z) ((complex ,type) (complex ,type)) *)
+ '(complex (- (realpart w) (realpart z))
+ (- (imagpart w) (imagpart z))))
+ ;; Add and subtract a complex and a real.
+ #!-complex-float-vops
+ (deftransform + ((w z) ((complex ,type) real) *)
+ `(complex (+ (realpart w) z)
+ (+ (imagpart w) ,(coerce 0 ',type))))
+ #!-complex-float-vops
+ (deftransform + ((z w) (real (complex ,type)) *)
+ `(complex (+ (realpart w) z)
+ (+ (imagpart w) ,(coerce 0 ',type))))
+ ;; Add and subtract a real and a complex number.
+ #!-complex-float-vops
+ (deftransform - ((w z) ((complex ,type) real) *)
+ `(complex (- (realpart w) z)
+ (- (imagpart w) ,(coerce 0 ',type))))
+ #!-complex-float-vops
+ (deftransform - ((z w) (real (complex ,type)) *)
+ `(complex (- z (realpart w))
+ (- ,(coerce 0 ',type) (imagpart w))))
+ ;; Multiply and divide two complex numbers.
+ #!-complex-float-vops
+ (deftransform * ((x y) ((complex ,type) (complex ,type)) *)
+ '(let* ((rx (realpart x))
+ (ix (imagpart x))
+ (ry (realpart y))
+ (iy (imagpart y)))
+ (complex (- (* rx ry) (* ix iy))
+ (+ (* rx iy) (* ix ry)))))
+ (deftransform / ((x y) ((complex ,type) (complex ,type)) *)
+ #!-complex-float-vops
+ '(let* ((rx (realpart x))
+ (ix (imagpart x))
+ (ry (realpart y))
+ (iy (imagpart y)))
+ (if (> (abs ry) (abs iy))
+ (let* ((r (/ iy ry))
+ (dn (+ ry (* r iy))))
+ (complex (/ (+ rx (* ix r)) dn)
+ (/ (- ix (* rx r)) dn)))
+ (let* ((r (/ ry iy))
+ (dn (+ iy (* r ry))))
+ (complex (/ (+ (* rx r) ix) dn)
+ (/ (- (* ix r) rx) dn)))))
+ #!+complex-float-vops
+ `(let* ((cs (conjugate (sb!vm::swap-complex x)))
+ (ry (realpart y))
+ (iy (imagpart y)))
+ (if (> (abs ry) (abs iy))
+ (let* ((r (/ iy ry))
+ (dn (+ ry (* r iy))))
+ (/ (+ x (* cs r)) dn))
+ (let* ((r (/ ry iy))
+ (dn (+ iy (* r ry))))
+ (/ (+ (* x r) cs) dn)))))
+ ;; Multiply a complex by a real or vice versa.
+ #!-complex-float-vops
+ (deftransform * ((w z) ((complex ,type) real) *)
+ '(complex (* (realpart w) z) (* (imagpart w) z)))
+ #!-complex-float-vops
+ (deftransform * ((z w) (real (complex ,type)) *)
+ '(complex (* (realpart w) z) (* (imagpart w) z)))
+ ;; Divide a complex by a real or vice versa.
+ #!-complex-float-vops
+ (deftransform / ((w z) ((complex ,type) real) *)
+ '(complex (/ (realpart w) z) (/ (imagpart w) z)))
+ (deftransform / ((x y) (,type (complex ,type)) *)
+ #!-complex-float-vops
+ '(let* ((ry (realpart y))
+ (iy (imagpart y)))
+ (if (> (abs ry) (abs iy))
+ (let* ((r (/ iy ry))
+ (dn (+ ry (* r iy))))
+ (complex (/ x dn)
+ (/ (- (* x r)) dn)))
+ (let* ((r (/ ry iy))
+ (dn (+ iy (* r ry))))
+ (complex (/ (* x r) dn)
+ (/ (- x) dn)))))
+ #!+complex-float-vops
+ '(let* ((ry (realpart y))
+ (iy (imagpart y)))
+ (if (> (abs ry) (abs iy))
+ (let* ((r (/ iy ry))
+ (dn (+ ry (* r iy))))
+ (/ (complex x (- (* x r))) dn))
+ (let* ((r (/ ry iy))
+ (dn (+ iy (* r ry))))
+ (/ (complex (* x r) (- x)) dn)))))
+ ;; conjugate of complex number
+ #!-complex-float-vops
+ (deftransform conjugate ((z) ((complex ,type)) *)
+ '(complex (realpart z) (- (imagpart z))))
+ ;; CIS
+ (deftransform cis ((z) ((,type)) *)
+ '(complex (cos z) (sin z)))
+ ;; comparison
+ #!-complex-float-vops
+ (deftransform = ((w z) ((complex ,type) (complex ,type)) *)
+ '(and (= (realpart w) (realpart z))
+ (= (imagpart w) (imagpart z))))
+ #!-complex-float-vops
+ (deftransform = ((w z) ((complex ,type) real) *)
+ '(and (= (realpart w) z) (zerop (imagpart w))))
+ #!-complex-float-vops
+ (deftransform = ((w z) (real (complex ,type)) *)
+ '(and (= (realpart z) w) (zerop (imagpart z)))))))
(frob single-float)
(frob double-float))
;;; inputs are union types.
#-sb-xc-host ; (See CROSS-FLOAT-INFINITY-KLUDGE.)
(progn
-(defun trig-derive-type-aux (arg domain fcn
- &optional def-lo def-hi (increasingp t))
+(defun trig-derive-type-aux (arg domain fun
+ &optional def-lo def-hi (increasingp t))
(etypecase arg
(numeric-type
(cond ((eq (numeric-type-complexp arg) :complex)
- (make-numeric-type :class (numeric-type-class arg)
- :format (numeric-type-format arg)
- :complexp :complex))
- ((numeric-type-real-p arg)
- (let* ((format (case (numeric-type-class arg)
- ((integer rational) 'single-float)
- (t (numeric-type-format arg))))
- (bound-type (or format 'float)))
- ;; If the argument is a subset of the "principal" domain
- ;; of the function, we can compute the bounds because
- ;; the function is monotonic. We can't do this in
- ;; general for these periodic functions because we can't
- ;; (and don't want to) do the argument reduction in
- ;; exactly the same way as the functions themselves do
- ;; it.
- (if (csubtypep arg domain)
- (let ((res-lo (bound-func fcn (numeric-type-low arg)))
- (res-hi (bound-func fcn (numeric-type-high arg))))
- (unless increasingp
- (rotatef res-lo res-hi))
- (make-numeric-type
- :class 'float
- :format format
- :low (coerce-numeric-bound res-lo bound-type)
- :high (coerce-numeric-bound res-hi bound-type)))
- (make-numeric-type
- :class 'float
- :format format
- :low (and def-lo (coerce def-lo bound-type))
- :high (and def-hi (coerce def-hi bound-type))))))
- (t
- (float-or-complex-float-type arg def-lo def-hi))))))
+ (make-numeric-type :class (numeric-type-class arg)
+ :format (numeric-type-format arg)
+ :complexp :complex))
+ ((numeric-type-real-p arg)
+ (let* ((format (case (numeric-type-class arg)
+ ((integer rational) 'single-float)
+ (t (numeric-type-format arg))))
+ (bound-type (or format 'float)))
+ ;; If the argument is a subset of the "principal" domain
+ ;; of the function, we can compute the bounds because
+ ;; the function is monotonic. We can't do this in
+ ;; general for these periodic functions because we can't
+ ;; (and don't want to) do the argument reduction in
+ ;; exactly the same way as the functions themselves do
+ ;; it.
+ (if (csubtypep arg domain)
+ (let ((res-lo (bound-func fun (numeric-type-low arg) nil))
+ (res-hi (bound-func fun (numeric-type-high arg) nil)))
+ (unless increasingp
+ (rotatef res-lo res-hi))
+ (make-numeric-type
+ :class 'float
+ :format format
+ :low (coerce-numeric-bound res-lo bound-type)
+ :high (coerce-numeric-bound res-hi bound-type)))
+ (make-numeric-type
+ :class 'float
+ :format format
+ :low (and def-lo (coerce def-lo bound-type))
+ :high (and def-hi (coerce def-hi bound-type))))))
+ (t
+ (float-or-complex-float-type arg def-lo def-hi))))))
(defoptimizer (sin derive-type) ((num))
(one-arg-derive-type
(lambda (arg)
;; Derive the bounds if the arg is in [0, pi].
(trig-derive-type-aux arg
- (specifier-type `(float 0d0 ,pi))
- #'cos
- -1 1
- nil))
+ (specifier-type `(float 0d0 ,pi))
+ #'cos
+ -1 1
+ nil))
#'cos))
(defoptimizer (tan derive-type) ((num))
(lambda (arg)
;; Derive the bounds if the arg is in [-pi/2, pi/2].
(trig-derive-type-aux arg
- (specifier-type `(float ,(- (/ pi 2)) ,(/ pi 2)))
- #'tan
- nil nil))
+ (specifier-type `(float ,(- (/ pi 2)) ,(/ pi 2)))
+ #'tan
+ nil nil))
#'tan))
-;;; CONJUGATE always returns the same type as the input type.
-;;;
-;;; FIXME: ANSI allows any subtype of REAL for the components of COMPLEX.
-;;; So what if the input type is (COMPLEX (SINGLE-FLOAT 0 1))?
(defoptimizer (conjugate derive-type) ((num))
- (continuation-type num))
+ (one-arg-derive-type num
+ (lambda (arg)
+ (flet ((most-negative-bound (l h)
+ (and l h
+ (if (< (type-bound-number l) (- (type-bound-number h)))
+ l
+ (set-bound (- (type-bound-number h)) (consp h)))))
+ (most-positive-bound (l h)
+ (and l h
+ (if (> (type-bound-number h) (- (type-bound-number l)))
+ h
+ (set-bound (- (type-bound-number l)) (consp l))))))
+ (if (numeric-type-real-p arg)
+ (lvar-type num)
+ (let ((low (numeric-type-low arg))
+ (high (numeric-type-high arg)))
+ (let ((new-low (most-negative-bound low high))
+ (new-high (most-positive-bound low high)))
+ (modified-numeric-type arg :low new-low :high new-high))))))
+ #'conjugate))
(defoptimizer (cis derive-type) ((num))
(one-arg-derive-type num
- (lambda (arg)
- (sb!c::specifier-type
- `(complex ,(or (numeric-type-format arg) 'float))))
- #'cis))
+ (lambda (arg)
+ (sb!c::specifier-type
+ `(complex ,(or (numeric-type-format arg) 'float))))
+ #'cis))
) ; PROGN
\f
;;;; TRUNCATE, FLOOR, CEILING, and ROUND
(macrolet ((define-frobs (fun ufun)
- `(progn
- (defknown ,ufun (real) integer (movable foldable flushable))
- (deftransform ,fun ((x &optional by)
- (* &optional
- (constant-arg (member 1))))
- '(let ((res (,ufun x)))
- (values res (- x res)))))))
+ `(progn
+ (defknown ,ufun (real) integer (movable foldable flushable))
+ (deftransform ,fun ((x &optional by)
+ (* &optional
+ (constant-arg (member 1))))
+ '(let ((res (,ufun x)))
+ (values res (- x res)))))))
(define-frobs truncate %unary-truncate)
(define-frobs round %unary-round))
-;;; Convert (TRUNCATE x y) to the obvious implementation. We only want
-;;; this when under certain conditions and let the generic TRUNCATE
-;;; handle the rest. (Note: if Y = 1, the divide and multiply by Y
-;;; should be removed by other DEFTRANSFORMs.)
-(deftransform truncate ((x &optional y)
- (float &optional (or float integer)))
- (let ((defaulted-y (if y 'y 1)))
- `(let ((res (%unary-truncate (/ x ,defaulted-y))))
- (values res (- x (* ,defaulted-y res))))))
+(deftransform %unary-truncate ((x) (single-float))
+ `(%unary-truncate/single-float x))
+(deftransform %unary-truncate ((x) (double-float))
+ `(%unary-truncate/double-float x))
+
+;;; Convert (TRUNCATE x y) to the obvious implementation.
+;;;
+;;; ...plus hair: Insert explicit coercions to appropriate float types: Python
+;;; is reluctant it generate explicit integer->float coercions due to
+;;; precision issues (see SAFE-SINGLE-COERCION-P &co), but this is not an
+;;; issue here as there is no DERIVE-TYPE optimizer on specialized versions of
+;;; %UNARY-TRUNCATE, so the derived type of TRUNCATE remains the best we can
+;;; do here -- which is fine. Also take care not to add unnecassary division
+;;; or multiplication by 1, since we are not able to always eliminate them,
+;;; depending on FLOAT-ACCURACY. Finally, leave out the secondary value when
+;;; we know it is unused: COERCE is not flushable.
+(macrolet ((def (type other-float-arg-types)
+ (let ((unary (symbolicate "%UNARY-TRUNCATE/" type))
+ (coerce (symbolicate "%" type)))
+ `(deftransform truncate ((x &optional y)
+ (,type
+ &optional (or ,type ,@other-float-arg-types integer))
+ * :result result)
+ (let* ((result-type (and result
+ (lvar-derived-type result)))
+ (compute-all (and (values-type-p result-type)
+ (not (type-single-value-p result-type)))))
+ (if (or (not y)
+ (and (constant-lvar-p y) (= 1 (lvar-value y))))
+ (if compute-all
+ `(let ((res (,',unary x)))
+ (values res (- x (,',coerce res))))
+ `(let ((res (,',unary x)))
+ ;; Dummy secondary value!
+ (values res x)))
+ (if compute-all
+ `(let* ((f (,',coerce y))
+ (res (,',unary (/ x f))))
+ (values res (- x (* f (,',coerce res)))))
+ `(let* ((f (,',coerce y))
+ (res (,',unary (/ x f))))
+ ;; Dummy secondary value!
+ (values res x)))))))))
+ (def single-float ())
+ (def double-float (single-float)))
(deftransform floor ((number &optional divisor)
(float &optional (or integer float)))
(let ((defaulted-divisor (if divisor 'divisor 1)))
`(multiple-value-bind (tru rem) (truncate number ,defaulted-divisor)
(if (and (not (zerop rem))
- (if (minusp ,defaulted-divisor)
- (plusp number)
- (minusp number)))
- (values (1- tru) (+ rem ,defaulted-divisor))
- (values tru rem)))))
+ (if (minusp ,defaulted-divisor)
+ (plusp number)
+ (minusp number)))
+ (values (1- tru) (+ rem ,defaulted-divisor))
+ (values tru rem)))))
(deftransform ceiling ((number &optional divisor)
(float &optional (or integer float)))
(let ((defaulted-divisor (if divisor 'divisor 1)))
`(multiple-value-bind (tru rem) (truncate number ,defaulted-divisor)
(if (and (not (zerop rem))
- (if (minusp ,defaulted-divisor)
- (minusp number)
- (plusp number)))
- (values (1+ tru) (- rem ,defaulted-divisor))
- (values tru rem)))))
+ (if (minusp ,defaulted-divisor)
+ (minusp number)
+ (plusp number)))
+ (values (1+ tru) (- rem ,defaulted-divisor))
+ (values tru rem)))))
+
+(defknown %unary-ftruncate (real) float (movable foldable flushable))
+(defknown %unary-ftruncate/single (single-float) single-float
+ (movable foldable flushable))
+(defknown %unary-ftruncate/double (double-float) double-float
+ (movable foldable flushable))
+
+(defun %unary-ftruncate/single (x)
+ (declare (type single-float x))
+ (declare (optimize speed (safety 0)))
+ (let* ((bits (single-float-bits x))
+ (exp (ldb sb!vm:single-float-exponent-byte bits))
+ (biased (the single-float-exponent
+ (- exp sb!vm:single-float-bias))))
+ (declare (type (signed-byte 32) bits))
+ (cond
+ ((= exp sb!vm:single-float-normal-exponent-max) x)
+ ((<= biased 0) (* x 0f0))
+ ((>= biased (float-digits x)) x)
+ (t
+ (let ((frac-bits (- (float-digits x) biased)))
+ (setf bits (logandc2 bits (- (ash 1 frac-bits) 1)))
+ (make-single-float bits))))))
+
+(defun %unary-ftruncate/double (x)
+ (declare (type double-float x))
+ (declare (optimize speed (safety 0)))
+ (let* ((high (double-float-high-bits x))
+ (low (double-float-low-bits x))
+ (exp (ldb sb!vm:double-float-exponent-byte high))
+ (biased (the double-float-exponent
+ (- exp sb!vm:double-float-bias))))
+ (declare (type (signed-byte 32) high)
+ (type (unsigned-byte 32) low))
+ (cond
+ ((= exp sb!vm:double-float-normal-exponent-max) x)
+ ((<= biased 0) (* x 0d0))
+ ((>= biased (float-digits x)) x)
+ (t
+ (let ((frac-bits (- (float-digits x) biased)))
+ (cond ((< frac-bits 32)
+ (setf low (logandc2 low (- (ash 1 frac-bits) 1))))
+ (t
+ (setf low 0)
+ (setf high (logandc2 high (- (ash 1 (- frac-bits 32)) 1)))))
+ (make-double-float high low))))))
+
+(macrolet
+ ((def (float-type fun)
+ `(deftransform %unary-ftruncate ((x) (,float-type))
+ '(,fun x))))
+ (def single-float %unary-ftruncate/single)
+ (def double-float %unary-ftruncate/double))