[cmucl-commit] [git] CMU Common Lisp branch master updated. snapshot-2013-12-a-28-gbf11273
Raymond Toy
rtoy at common-lisp.net
Sat Dec 21 06:42:10 UTC 2013
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- Log -----------------------------------------------------------------
commit bf1127321b08ef7e02eb7159f194c054078b95f2
Author: Raymond Toy <toy.raymond at gmail.com>
Date: Fri Dec 20 22:41:59 2013 -0800
Document the value of atan better. The CLHS is confusing.
Clean up comments for asin too.
diff --git a/src/tests/trig.lisp b/src/tests/trig.lisp
index 78e643d..011aeaf 100644
--- a/src/tests/trig.lisp
+++ b/src/tests/trig.lisp
@@ -482,14 +482,16 @@
(complex 0 z)))
;; asin(x) = -i*log(i*x + sqrt(1-x^2))
-(defun asin-def (z)
- (- (i*z (log (+ (i*z z)
- (sqrt (1-z (* z z))))))))
-
-;; asin branch cut is the real axis |x| > 1. For x < -1, it is
+;;
+;; The branch cut is the real axis |x| > 1. For x < -1, it is
;; continuous with quadrant II; for x > 1, continuous with quadrant
;; IV.
;;
+(defun asin-def (z)
+ (- (i*z (log (+ (i*z z)
+ (sqrt (1-z (* z z))))))))
+
+
(define-test branch-cut.asin
(:tag :asin :branch-cuts)
;; Test for x < -1, which is continuous with Quadrant II. Compute
@@ -566,6 +568,33 @@
;; atan(z) = (log(1+i*z) - log(1-i*z))/(2*i)
;; = -i/2*(log(1+i*z) - log(1-i*z))
;;
+;; WARNING: The CLHS is a bit confused here. Two definitions of atan
+;; are given in the CLHS
+;; http://www.lispworks.com/documentation/HyperSpec/Body/f_asin_.htm
+;; and they are not consistent. Plus, there is a typo in the second
+;; definition. (Missing parens.)
+;;
+;; For clarification, we turn to
+;; http://www.lispworks.com/documentation/HyperSpec/Issues/iss069_w.htm,
+;; which recommends using the second formula and also puts in the
+;; parentheses in the correct places.
+;;
+;; BUT, this is further confused by the example that atan(0+2*i) is
+;; 1.57-0.549*i for the proposed formula but -1.57+0.549*i under the
+;; current formula.
+;;
+;;
+;; I think the inconsistency is that the results are derived without
+;; signed zeroes. But we have signed zeroes, so let us derive the
+;; actual value of atan(0+2*i) using the (second) formula.
+;;
+;; atan(0+2*i) = (log(1+i*(0+2*i)) - log(1-i*(0+2*i)))/(2*i)
+;; = (log(1+(-2+0*i)) - log(1-(-2+0*i)))/(2*i)
+;; = (log(-1-0*i) - log(3-0*i))/(2*i)
+;; = ((log(1) - pi*i) - (log(3) - 0*i))/(2*i)
+;; = (-log(3) - pi*i)/(2*i)
+;; = -pi/2 + log(3)/2*i
+;;
;; The branch cut is the imaginary axis, |y| > 1. For y < -1, atan is
;; continuous with Quadrant IV; for y > 1, Quadrant II.
(defun atan-def (z)
commit 196e1482e0563250b4ca257a2a119dbe09e6b0a3
Author: Raymond Toy <toy.raymond at gmail.com>
Date: Fri Dec 20 22:16:27 2013 -0800
Add tests for branch cuts.
diff --git a/src/tests/trig.lisp b/src/tests/trig.lisp
index 58d5440..78e643d 100644
--- a/src/tests/trig.lisp
+++ b/src/tests/trig.lisp
@@ -228,6 +228,8 @@
t
err)))
+
+;;; Tests for double-double-floats
(define-test dd-sin.signed-zeroes
"Test sin for 0w0 and -0w0"
(:tag :sin :double-double :signed-zeroes)
@@ -431,3 +433,169 @@
(assert-eql nil
(dd-sincos-test (scale-float 1w0 1023) 1000)))
+
+;;; Tests for branch cuts.
+
+
+;; Compute fun(arg) and check that the signs of the real and imaginary
+;; parts match the value of real-sign and imag-sign, respectively.
+;; Return T if the signs match.
+(defun check-signs (fun arg real-sign imag-sign)
+ (let* ((z (funcall fun arg))
+ (x (realpart z))
+ (y (imagpart z)))
+ (cond ((and (= (float-sign x) real-sign)
+ (= (float-sign y) imag-sign))
+ t)
+ (t
+ (format t "Sign of result doesn't match expected signs~%~
+ ~& fun = ~A~
+ ~& arg = ~A~
+ ~& res = ~A~
+ ~& expected = ~A ~A~%"
+ fun arg z real-sign imag-sign)
+ nil))))
+
+;; Return the signs of the real and imaginary parts of z.
+(defun get-signs (z)
+ (values (float-sign (realpart z))
+ (float-sign (imagpart z))))
+
+;; Carefully compute 1-z. For z = x + i*y, we want 1-x - i*y, which
+;; only really matters when y is a signed zero.
+(defun 1-z (z)
+ (if (complexp z)
+ (complex (- 1 (realpart z)) (- (imagpart z)))
+ (- 1 z)))
+
+;; Carefully compute 1+z. For z = x + i*y, we want 1+x + i*y, which
+;; only really matters when y is a signed zero.
+(defun 1+z (z)
+ (if (complexp z)
+ (complex (+ 1 (realpart z)) (imagpart z))
+ (+ 1 z)))
+
+;; Carefully compute i*z = i*(x+i*y) = -y + i*x.
+(defun i*z (z)
+ (if (complexp z)
+ (complex (- (imagpart z)) (realpart z))
+ (complex 0 z)))
+
+;; asin(x) = -i*log(i*x + sqrt(1-x^2))
+(defun asin-def (z)
+ (- (i*z (log (+ (i*z z)
+ (sqrt (1-z (* z z))))))))
+
+;; asin branch cut is the real axis |x| > 1. For x < -1, it is
+;; continuous with quadrant II; for x > 1, continuous with quadrant
+;; IV.
+;;
+(define-test branch-cut.asin
+ (:tag :asin :branch-cuts)
+ ;; Test for x < -1, which is continuous with Quadrant II. Compute
+ ;; the value at #c(-2d0 1d-10) and check that components of
+ ;; asin(-2+0.0*i) have the same signs as the reference value.
+ (multiple-value-bind (tr ti)
+ (get-signs (asin-def #c(-2d0 1d-20)))
+ (assert-true (check-signs #'asin -2d0 tr ti))
+ (assert-true (check-signs #'asin -2w0 tr ti))
+ (assert-true (check-signs #'asin #c(-2d0 0) tr ti))
+ (assert-true (check-signs #'asin #c(-2w0 0) tr ti)))
+ ;; Test the other side of the branch cut for x < -1.
+ (multiple-value-bind (tr ti)
+ (get-signs (asin-def #c(-2d0 -1d-20)))
+ (assert-true (check-signs #'asin #c(-2d0 -0d0) tr ti))
+ (assert-true (check-signs #'asin #c(-2w0 -0w0) tr ti)))
+
+ ;; Test for x > 1, which is continuous with Quadrant IV, using the
+ ;; value at #c(+2d0 1d-10) as the reference
+ (multiple-value-bind (tr ti)
+ (get-signs (asin-def #c(2d0 1d-20)))
+ (assert-true (check-signs #'asin #c(2d0 0) tr ti))
+ (assert-true (check-signs #'asin #c(2w0 0) tr ti)))
+ ;; Test the other side of the branch cut for x > 1.
+ (multiple-value-bind (tr ti)
+ (get-signs (asin-def #c(2d0 -1d-20)))
+ (assert-true (check-signs #'asin 2d0 tr ti))
+ (assert-true (check-signs #'asin 2w0 tr ti))
+ (assert-true (check-signs #'asin #c(2d0 -0d0) tr ti))
+ (assert-true (check-signs #'asin #c(2w0 -0w0) tr ti))))
+
+;; acos(z) = pi/2 - asin(z).
+;;
+;; The branch cut is the real axis for |x| > 1. For x < -1, it is
+;; continous with Quadrant II; for x > 1, Quadrant IV.
+(defun acos-def (z)
+ (if (typep z 'kernel:double-double-float)
+ (- (/ kernel:dd-pi 2)
+ (asin-def z))
+ (- (/ pi 2)
+ (asin-def z))))
+
+(define-test branch-cut.acos
+ (:tag :acos :branch-cuts)
+ ;; Test for x < -1, which is continuous with Quadrant II. Compute
+ ;; the value at #c(-2d0 1d-10) and check that components of
+ ;; acos(-2+0.0*i) have the same signs as the reference value.
+ (multiple-value-bind (tr ti)
+ (get-signs (acos-def #c(-2d0 1d-20)))
+ (assert-true (check-signs #'acos -2d0 tr ti))
+ (assert-true (check-signs #'acos -2w0 tr ti))
+ (assert-true (check-signs #'acos #c(-2d0 0) tr ti))
+ (assert-true (check-signs #'acos #c(-2w0 0) tr ti)))
+ ;; Test the other side of the branch cut for x < -1.
+ (multiple-value-bind (tr ti)
+ (get-signs (acos-def #c(-2d0 -1d-20)))
+ (assert-true (check-signs #'acos #c(-2d0 -0d0) tr ti))
+ (assert-true (check-signs #'acos #c(-2w0 -0w0) tr ti)))
+
+ ;; Test for x > 1, which is continuous with Quadrant IV, using the
+ ;; value at #c(+2d0 1d-10) as the reference
+ (multiple-value-bind (tr ti)
+ (get-signs (acos-def #c(2d0 1d-20)))
+ (assert-true (check-signs #'acos #c(2d0 0) tr ti))
+ (assert-true (check-signs #'acos #c(2w0 0) tr ti)))
+ ;; Test the other side of the branch cut for x > 1.
+ (multiple-value-bind (tr ti)
+ (get-signs (acos-def #c(2d0 -1d-20)))
+ (assert-true (check-signs #'acos 2d0 tr ti))
+ (assert-true (check-signs #'acos 2w0 tr ti))
+ (assert-true (check-signs #'acos #c(2d0 -0d0) tr ti))
+ (assert-true (check-signs #'acos #c(2w0 -0w0) tr ti))))
+
+;; atan(z) = (log(1+i*z) - log(1-i*z))/(2*i)
+;; = -i/2*(log(1+i*z) - log(1-i*z))
+;;
+;; The branch cut is the imaginary axis, |y| > 1. For y < -1, atan is
+;; continuous with Quadrant IV; for y > 1, Quadrant II.
+(defun atan-def (z)
+ (let* ((iz (i*z z))
+ (w (- (log (1+z iz))
+ (log (1-z iz)))))
+ (* -1/2 (i*z w))))
+
+(define-test branch-cut.atan
+ (:tag :atan :branch-cuts)
+ ;; Test for y < -1, which is continuous with Quadrant IV. Use the
+ ;; value at #c(1d-20 -2d0) as the reference.
+ (multiple-value-bind (tr ti)
+ (get-signs (atan-def #c(1d-20 -2d0)))
+ (assert-true (check-signs #'atan #c(0d0 -2d0) tr ti))
+ (assert-true (check-signs #'atan #c(0w0 -2w0) tr ti)))
+ ;; Test the other side of the branch cut for x < -1.
+ (multiple-value-bind (tr ti)
+ (get-signs (atan-def #c(-1d-20 -2d0)))
+ (assert-true (check-signs #'atan #c(-0d0 -2d0) tr ti))
+ (assert-true (check-signs #'atan #c(-0w0 -2w0) tr ti)))
+
+ ;; Test for y > 1, which is continuous with Quadrant II, using the
+ ;; value at #c(-1d-20 +2d0) as the reference
+ (multiple-value-bind (tr ti)
+ (get-signs (atan-def #c(-1d-20 2d0)))
+ (assert-true (check-signs #'atan #c(-0d0 2d0) tr ti))
+ (assert-true (check-signs #'atan #c(-0w0 2w0) tr ti)))
+ ;; Test the other side of the branch cut for x > 1.
+ (multiple-value-bind (tr ti)
+ (get-signs (atan-def #c(1d-20 2d0)))
+ (assert-true (check-signs #'atan #c(0d0 2d0) tr ti))
+ (assert-true (check-signs #'atan #c(0d0 2w0) tr ti))))
-----------------------------------------------------------------------
Summary of changes:
src/tests/trig.lisp | 197 +++++++++++++++++++++++++++++++++++++++++++++++++++
1 file changed, 197 insertions(+)
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