;;;; While most of SBCL is derived from the CMU CL system, the test
;;;; files (like this one) were written from scratch after the fork
;;;; from CMU CL.
-;;;;
+;;;;
;;;; This software is in the public domain and is provided with
;;;; absolutely no warranty. See the COPYING and CREDITS files for
;;;; more information.
;;; e.g. someone inadvertently ports the bad code.
(defun point39 (x y)
(make-array 2
- :element-type 'double-float
+ :element-type 'double-float
:initial-contents (list x y)))
(declaim (inline point39-x point39-y))
(aref p 1))
(defun order39 (points)
(sort points (lambda (p1 p2)
- (let* ((y1 (point39-y p1))
- (y2 (point39-y p2)))
- (if (= y1 y2)
- (< (point39-x p1)
- (point39-x p2))
- (< y1 y2))))))
+ (let* ((y1 (point39-y p1))
+ (y2 (point39-y p2)))
+ (if (= y1 y2)
+ (< (point39-x p1)
+ (point39-x p2))
+ (< y1 y2))))))
(defun test39 ()
(order39 (make-array 4
- :initial-contents (list (point39 0.0d0 0.0d0)
- (point39 1.0d0 1.0d0)
- (point39 2.0d0 2.0d0)
- (point39 3.0d0 3.0d0)))))
+ :initial-contents (list (point39 0.0d0 0.0d0)
+ (point39 1.0d0 1.0d0)
+ (point39 2.0d0 2.0d0)
+ (point39 3.0d0 3.0d0)))))
(assert (equalp (test39)
- #(#(0.0d0 0.0d0)
- #(1.0d0 1.0d0)
- #(2.0d0 2.0d0)
- #(3.0d0 3.0d0))))
+ #(#(0.0d0 0.0d0)
+ #(1.0d0 1.0d0)
+ #(2.0d0 2.0d0)
+ #(3.0d0 3.0d0))))
+
+(defun complex-double-float-ppc (x y)
+ (declare (type (complex double-float) x y))
+ (declare (optimize speed))
+ (+ x y))
+(compile 'complex-double-float-ppc)
+(assert (= (complex-double-float-ppc #c(0.0d0 1.0d0) #c(2.0d0 3.0d0))
+ #c(2.0d0 4.0d0)))
+
+(defun single-float-ppc (x)
+ (declare (type (signed-byte 32) x) (optimize speed))
+ (float x 1f0))
+(compile 'single-float-ppc)
+(assert (= (single-float-ppc -30) -30f0))
+
+;;; constant-folding irrational functions
+(declaim (inline df))
+(defun df (x)
+ ;; do not remove the ECASE here: the bug this checks for indeed
+ ;; depended on this configuration
+ (ecase x (1 least-positive-double-float)))
+(macrolet ((test (fun)
+ (let ((name (intern (format nil "TEST-CONSTANT-~A" fun))))
+ `(progn
+ (defun ,name () (,fun (df 1)))
+ (,name)))))
+ (test sqrt)
+ (test log)
+ (test sin)
+ (test cos)
+ (test tan)
+ (test asin)
+ (test acos)
+ (test atan)
+ (test sinh)
+ (test cosh)
+ (test tanh)
+ (test asinh)
+ (test acosh)
+ (test atanh)
+ (test exp))
+
+;;; Broken move-arg-double-float for non-rsp frame pointers on x86-64
+(defun test (y)
+ (declare (optimize speed))
+ (multiple-value-bind (x)
+ (labels ((aux (x)
+ (declare (double-float x))
+ (etypecase y
+ (double-float
+ nil)
+ (fixnum
+ (aux x))
+ (complex
+ (format t "y=~s~%" y)))
+ (values x)))
+ (aux 2.0d0))
+ x))
+
+(assert (= (test 1.0d0) 2.0d0))
+
+(deftype myarraytype (&optional (length '*))
+ `(simple-array double-float (,length)))
+(defun new-pu-label-from-pu-labels (array)
+ (setf (aref (the myarraytype array) 0)
+ sb-ext:double-float-positive-infinity))
+
+;;; bug 407
+;;;
+;;; FIXME: it may be that TYPE-ERROR is wrong, and we should
+;;; instead signal an overflow or coerce into an infinity.
+(defun bug-407a ()
+ (loop for n from (expt 2 1024) upto (+ 10 (expt 2 1024))
+ do (handler-case
+ (coerce n 'single-float)
+ (simple-type-error ()
+ (return-from bug-407a :type-error)))))
+(assert (eq :type-error (bug-407a)))
+(defun bug-407b ()
+ (loop for n from (expt 2 1024) upto (+ 10 (expt 2 1024))
+ do (handler-case
+ (format t "~E~%" (coerce n 'single-float))
+ (simple-type-error ()
+ (return-from bug-407b :type-error)))))
+(assert (eq :type-error (bug-407b)))
+
+;; 1.0.29.44 introduces a ton of changes for complex floats
+;; on x86-64. Huge test of doom to help catch weird corner
+;; cases.
+;; Abuse the framework to also test some float arithmetic
+;; changes wrt constant arguments in 1.0.29.54.
+(defmacro def-compute (name real-type
+ &optional (complex-type `(complex ,real-type)))
+ `(defun ,name (x y r)
+ (declare (type ,complex-type x y)
+ (type ,real-type r))
+ (flet ((reflections (x)
+ (values x
+ (conjugate x)
+ (complex (- (realpart x)) (imagpart x))
+ (- x)))
+ (compute (x y r)
+ (declare (type ,complex-type x y)
+ (type ,real-type r))
+ (list (1+ x) (* 2 x) (/ x 2) (= 1 x)
+ (+ x y) (+ r x) (+ x r)
+ (- x y) (- r x) (- x r)
+ (* x y) (* x r) (* r x)
+ (unless (zerop y)
+ (/ x y))
+ (unless (zerop r)
+ (/ x r))
+ (unless (zerop x)
+ (/ r x))
+ (conjugate x) (conjugate r)
+ (abs r) (- r) (= 1 r)
+ (- x) (1+ r) (* 2 r) (/ r 2)
+ (complex r) (complex r r) (complex 0 r)
+ (= x y) (= r x) (= y r) (= x (complex 0 r))
+ (= r (realpart x)) (= (realpart x) r)
+ (> r (realpart x)) (< r (realpart x))
+ (> (realpart x) r) (< (realpart x) r)
+ (eql x y) (eql x (complex r)) (eql y (complex r))
+ (eql x (complex r r)) (eql y (complex 0 r))
+ (eql r (realpart x)) (eql (realpart x) r))))
+ (declare (inline reflections))
+ (multiple-value-bind (x1 x2 x3 x4) (reflections x)
+ (multiple-value-bind (y1 y2 y3 y4) (reflections y)
+ #.(let ((form '(list)))
+ (dolist (x '(x1 x2 x3 x4) (reverse form))
+ (dolist (y '(y1 y2 y3 y4))
+ (push `(list ,x ,y r
+ (append (compute ,x ,y r)
+ (compute ,x ,y (- r))))
+ form)))))))))
+
+(def-compute compute-number real number)
+(def-compute compute-single single-float)
+(def-compute compute-double double-float)
+
+(labels ((equal-enough (x y)
+ (cond ((eql x y))
+ ((or (complexp x)
+ (complexp y))
+ (or (eql (coerce x '(complex double-float))
+ (coerce y '(complex double-float)))
+ (and (equal-enough (realpart x) (realpart y))
+ (equal-enough (imagpart x) (imagpart y)))))
+ ((numberp x)
+ (or (eql (coerce x 'double-float) (coerce y 'double-float))
+ (< (abs (- x y)) 1d-5))))))
+ (let* ((reals '(0 1 2))
+ (complexes '#.(let ((reals '(0 1 2))
+ (cpx '()))
+ (dolist (x reals (nreverse cpx))
+ (dolist (y reals)
+ (push (complex x y) cpx))))))
+ (declare (notinline every))
+ (dolist (r reals)
+ (dolist (x complexes)
+ (dolist (y complexes)
+ (let ((value (compute-number x y r))
+ (single (compute-single (coerce x '(complex single-float))
+ (coerce y '(complex single-float))
+ (coerce r 'single-float)))
+ (double (compute-double (coerce x '(complex double-float))
+ (coerce y '(complex double-float))
+ (coerce r 'double-float))))
+ (assert (every (lambda (pos ref single double)
+ (declare (ignorable pos))
+ (every (lambda (ref single double)
+ (or (and (equal-enough ref single)
+ (equal-enough ref double))
+ (and (not (numberp single)) ;; -ve 0s
+ (equal-enough single double))))
+ (fourth ref) (fourth single) (fourth double)))
+ '((0 0) (0 1) (0 2) (0 3)
+ (1 0) (1 1) (1 2) (1 3)
+ (2 0) (2 1) (2 2) (2 3)
+ (3 0) (3 1) (3 2) (3 3))
+ value single double))))))))
+
+;; The x86 port used not to reduce the arguments of transcendentals
+;; correctly.
+;; This test is valid only for x86: The x86 port uses the builtin x87
+;; FPU instructions to implement the trigonometric functions; other
+;; ports rely on the system's math library. These two differ in the
+;; precision of pi used for the range reduction and so yield results
+;; that can differ by arbitrarily large amounts for large inputs.
+;; The test expects the x87 results.
+(with-test (:name (:range-reduction :x87)
+ :skipped-on '(not :x86))
+ (flet ((almost= (x y)
+ (< (abs (- x y)) 1d-5)))
+ (macrolet ((foo (op value)
+ `(let ((actual (,op ,value))
+ (expected (,op (mod ,value (* 2 pi)))))
+ (unless (almost= actual expected)
+ (error "Inaccurate result for ~a: expected ~a, got ~a"
+ (list ',op ,value) expected actual)))))
+ (let ((big (* pi (expt 2d0 70)))
+ (mid (coerce most-positive-fixnum 'double-float))
+ (odd (* pi most-positive-fixnum)))
+ (foo sin big)
+ (foo sin mid)
+ (foo sin odd)
+ (foo sin (/ odd 2d0))
+
+ (foo cos big)
+ (foo cos mid)
+ (foo cos odd)
+ (foo cos (/ odd 2d0))
+
+ (foo tan big)
+ (foo tan mid)
+ (foo tan odd)))))
+
+;; To test the range reduction of trigonometric functions we need a much
+;; more accurate approximation of pi than CL:PI is. Calculating this is
+;; more fun than copy-pasting a constant and Gauss-Legendre converges
+;; extremely fast.
+(defun pi-gauss-legendre (n-bits)
+ "Return a rational approximation to pi using the Gauss-Legendre
+algorithm. The calculations are done with integers, representing
+multiples of (expt 2 (- N-BITS)), and the result is an integral multiple
+of this number. The result is accurate to a few less than N-BITS many
+fractional bits."
+ (let ((a (ash 1 n-bits)) ; scaled 1
+ (b (isqrt (expt 2 (1- (* n-bits 2))))) ; scaled (sqrt 1/2)
+ (c (ash 1 (- n-bits 2))) ; scaled 1/4
+ (d 0))
+ (loop
+ (when (<= (- a b) 1)
+ (return))
+ (let ((a1 (ash (+ a b) -1)))
+ (psetf a a1
+ b (isqrt (* a b))
+ c (- c (ash (expt (- a a1) 2) (- d n-bits)))
+ d (1+ d))))
+ (/ (round (expt (+ a b) 2) (* 4 c))
+ (ash 1 n-bits))))
-;;; success
-(quit :unix-status 104)
+;; Test that the range reduction of trigonometric functions is done
+;; with a sufficiently accurate value of pi that the reduced argument
+;; is correct to nearly double-float precision even for arguments of
+;; very large absolute value.
+;; This test is skipped on x86; as to why see the comment at the test
+;; (:range-reduction :x87) above.
+(with-test (:name (:range-reduction :precise-pi)
+ :skipped-on :x86)
+ (let ((rational-pi-half (/ (pi-gauss-legendre 2200) 2)))
+ (labels ((round-pi-half (x)
+ "Return two values as if (ROUND X (/ PI 2)) was called
+ but where PI is precise enough that for all possible
+ double-float arguments the quotient is exact and the
+ remainder is exact to double-float precision."
+ (declare (type double-float x))
+ (multiple-value-bind (q r)
+ (round (rational x) rational-pi-half)
+ (values q (coerce r 'double-float))))
+ (expected-val (op x)
+ "Calculate (OP X) precisely by shifting the argument by
+ an integral multiple of (/ PI 2) into the range from
+ (- (/ PI 4)) to (/ PI 4) and applying the phase-shift
+ formulas for the trigonometric functions. PI here is
+ precise enough that the result is exact to double-float
+ precision."
+ (labels ((precise-val (op q r)
+ (ecase op
+ (sin (let ((x (if (zerop (mod q 2))
+ (sin r)
+ (cos r))))
+ (if (<= (mod q 4) 1)
+ x
+ (- x))))
+ (cos (precise-val 'sin (1+ q) r))
+ (tan (if (zerop (mod q 2))
+ (tan r)
+ (/ (- (tan r))))))))
+ (multiple-value-bind (q r)
+ (round-pi-half x)
+ (precise-val op q r))))
+ (test (op x)
+ (let ((actual (funcall op x))
+ (expected (expected-val op x)))
+ ;; Some of the test values are chosen to lie very near
+ ;; to an integral multiple of pi/2 (within a distance of
+ ;; between 1d-11 and 1d-8), making the absolute value of
+ ;; their sine or cosine this small, too. The absolute
+ ;; value of the tangent is then either similarly small or
+ ;; as large as the reciprocal of this value. Therefore we
+ ;; measure relative instead of absolute error.
+ (unless (or (= actual expected 0)
+ (and (= (signum actual) (signum expected))
+ (< (abs (/ (- actual expected)
+ (+ actual expected)))
+ (* 8 double-float-epsilon))))
+ (error "Inaccurate result for ~a: expected ~a, got ~a"
+ (list op x) expected actual)))))
+ (dolist (op '(sin cos tan))
+ (dolist (val `(,(coerce most-positive-fixnum 'double-float)
+ ,@(loop for v = most-positive-double-float
+ then (expt v 4/5)
+ while (> v (expt 2 50))
+ collect v)
+ ;; The following values cover all eight combinations
+ ;; of values slightly below or above integral
+ ;; multiples of pi/2 with the integral factor
+ ;; congruent to 0, 1, 2 or 3 modulo 4.
+ 5.526916451564098d71
+ 4.913896894631919d229
+ 7.60175752894437d69
+ 3.8335637324151093d42
+ 1.8178427396473695d155
+ 9.41634760758887d89
+ 4.2766818550391727d188
+ 1.635888515419299d28))
+ (test op val))))))