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This is a follow-up to the question on double-float that I posted earlier. I apologize for what's probably a fundamental Lisp concept, but I haven't grasped it yet.

For this problem, I am using GNU CLISP 2.49 (2010-07-07).

Suppose I have the following function, which simply determines square root via Newton's method:

(defun sr (n eps)
  (when (>= n 0)
    (do ((x (/ n 2.0) (/ (+ x (/ n x)) 2.0)))
      ((< (abs (- (* x x) n)) eps)
       x))))

I can call this as follows:

> (sr 2 0.00001)
1.4142157

It's giving me single precision float (the default). Makes sense. Due to the lack of precision, if I make eps too small, it doesn't function properly and goes into an infinite loop:

> (sr 2 0.00000001)
[just sits there...]

If I call it with double precision values, I still get single precision results:

> (sr 2.0d0 0.00001d0)
1.4142157
> (sr 2.0d0 0.00000001d0)
[just sits there...]

But if I redefine my function as follows:

(defun sr (n eps)
  (when (>= n 0)
    (do ((x (/ n 2.0d0) (/ (+ x (/ n x)) 2.0d0)))
      ((< (abs (- (* x x) n)) eps)
       x))))

I then get double precision no matter how I feed it:

> (sr 2 0.00001)
1.4142156862745097d0

And now feeding it a smaller eps works due to the increased precision:

> (sr 2 0.00000001)
1.4142135623746899d0

So my question is: is the precision applied by the function totally driven by the precision I specify in the constants it is using in the arithmetic expressions it contains? And if so, what if there were no constants anywhere in the function? What then determines the precision of the calculations and the result?


ADDENDUM

I just retested this on SBCL 1.0.57-1.fc17 and I get much more expected results, per the documentation that @JoshuaTaylor quoted in the comment.

share|improve this question
    
12.1.4.4 Rule of Float Precision Contagion says, "The result of a numerical function is a float of the largest format among all the floating-point arguments to the function." That sounds like if you put a double float in, you should get a double float out. The behavior you're getting is interesting… – Joshua Taylor Jan 25 '14 at 22:09
    
@JoshuaTaylor I updated my question to indicate that I'm using GNU CLISP 2.49. – lurker Jan 25 '14 at 22:11
    
See my answer. This has a setting in CLISP. – Rainer Joswig Jan 25 '14 at 22:20
up vote 4 down vote accepted

Looks to me like this is an incompatibility of CLISP with the ANSI CL Standard.

The ANSI CL standard requires the result to be the largest type of all arguments:

CL-USER 20 > (/ 2.0d0 2.0)
1.0D0

CLISP gives:

[4]> (/ 2.0d0 2.0)
1.0

This should be a double float.

You can change that in CLISP to standard ANSI CL behavior:

[9]> CUSTOM:*FLOATING-POINT-CONTAGION-ANSI*
NIL
[10]> (setf CUSTOM:*FLOATING-POINT-CONTAGION-ANSI* t)
T
[11]> (sr 2.0d0 0.00001d0)
1.4142156862745097d0

Now it gives back the desired result.

See the CLISP manual: 12.2.4.1. Rule of Float Precision Contagion

share|improve this answer
    
Ah... I just tried it with SBCL and it actually works as expected. So I agree with this response. :) – lurker Jan 25 '14 at 22:13
    
That's interesting. I wonder why the default for *FLOATING-POINT-CONTAGION-ANSI* wouldn't be T. But that bit of documentation does absolve CLISP of some amount of guilt. ;) – lurker Jan 25 '14 at 22:21
    
@Rainer you beat me to it; I googled for CLISP and 12.1.4.4 and came up with this post that mentions the setting: groups.google.com/d/msg/comp.lang.lisp/Z3orriYcDT8/Bw57u1MQzYEJ, Well done! – Joshua Taylor Jan 25 '14 at 22:21
    
@mrbatch: see the manual topic I've linked. It's explained there... – Rainer Joswig Jan 25 '14 at 22:23
    
That section is a very interesting read. And it's fascinating that CLISP developers took that singular stance versus the ANSI default (understandable based upon their explanation). – lurker Jan 25 '14 at 22:43

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