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I'm using Codeblocks + GNU Fortran.

The problem is that I have calculations like:

SQRT(1-COS*COS)

And when I do these calculations a lot (a few million times) sometimes the value under square root is negative and therefore I get NaNs in result.

My efforts have shown that when square root is being calculated for a negative number COS equals "-1". Therefore, fortran counts -1*-1 incorrectly as there should be 0 under square root but there isn't.

Is there a way to solve this problem? This concerns not only pythagorean trigonometric identity but anything under square root looking like

SQRT(1-x*x)

With X being in range of [-1,1].

Basically COST is defined like this in my program (I apologize for somewhat lengthy introduction before COST itself but that's how it goes):

XDET = 0.
YDET = 0.
ZDET = 50.
RADIUS = 1.

x = RADIUS*sqrt(omega)  !omega=random number in uniform distribution [0,1]
y = 0.
z = 1.E-20

DW=SQRT((XDET-X)**2+(YDET-Y)**2+(ZDET-Z)**2)
DWW = 1./DW
AN2=(ZDET-Z)*DWW

COST = AN2
if(COST > 1. ) COST = 1.
if(COST < -1.) COST = -1.
SINT = SQRT(1.-COST*COST)

By the way, the AN2 sometimes assumed an absolute zero that lead to NaNs as well before I trapped it.

P.S. I also have a bug of EXP(X) with X being higher than 90 showing up as INFINITY.

share|improve this question
    
How certain are you that |COS| can never be greater than 1.0? – Ignacio Vazquez-Abrams Dec 5 '13 at 13:29
    
Show us your code. As it stands the expression SQRT(1-COS*COS) can only be parsed successfully if COS is the name of a variable, it is not a call to the intrinsic function COS, nor to any other function. While AlexanderVogt may be on the right lines, I'm reserving judgement. – High Performance Mark Dec 5 '13 at 13:36
    
High Performance Mark, see the edited post for code excerpt. – Arthmost Dec 5 '13 at 14:17
    
Can you please specify your gfortran version and values of omega that caused the problem? I tested 1000 random numbers but have not been able to reproduce that problem. – Xiaolei Zhu Dec 5 '13 at 15:13
    
Xiaolei Zhu, I am sorry for stupid question but how do I determine my gfortran version if it's been installed with Codeblocks? – Arthmost Dec 5 '13 at 15:23

The explanation for what your PS identifies as a bug is simple

exp(90.0) > 3.4028235 x 10^38

and 3.4028235 x 10^38 is the largest positive number that a single-precision floating-point number can represent with any accuracy.

This analysis does, of course, assume that your variable x is an IEEE 32-bit floating-point number.

Note too, that the expression ZDET-Z will never, in single-precision, be different from 1.0. 1.0 - 1.0e-20 == 0.9999999999999999999 but representing this exactly exceeds the precision available and the number is rounded to 1.0.

While I still can't see how 1.-COST*COST would ever be negative your use of floating-point arithmetic isn't reassuring me that there aren't subtle mistakes in those parts of the code you haven't shown us.

share|improve this answer
    
Yeah, I've come to the same conclusion when I reckoned how much exp(90+) really is. Thank you. – Arthmost Dec 5 '13 at 15:20
    
Well, I am not really a great specialist on f-p arithmetic particularly considering that most of the code was provided by my scientific supervisor for me to be able to do my scientific work. If you could specify what I should correct to make the program more stable, I'd gladly do it as I'm fixing things here and there in the code as I learn more about Fortran. – Arthmost Dec 5 '13 at 15:54
1  
You should, if you haven't already, familiarise yourself with the Wikipedia article on floating-point. The paper to which Alexander Vogt points you, which is often pointed to, is highly technical and probably not a good first read on the topic. Once you understand what Wikipedia tells you, learn about Fortran's capabilities in this regard. Pay particular attention to the definition and use of numeric kinds. Study a text on numerical computation, I like Hamming's book Numerical Methods for Scientists and Engineers but there are many others. – High Performance Mark Dec 5 '13 at 16:04
1  
You can't do your scientific work without a good understanding of floating-point numbers and arithmetic any more than you can do it without a good understanding of (the relevant) mathematics. – High Performance Mark Dec 5 '13 at 16:06

My guess would be this is due to limited precision of floating point numbers. Take a look here: What Every Computer Scientist Should Know About Floating-Point Arithmetic.

Simple solution:

xx = x*x
if ( xx .gt. 1.e0 ) xx = 1.e0 ! 1.d0 for double precision

y = sqrt( 1.e0 - xx ) ! Again, 1.d0 for double precision

Or, as a one-liner:

 y = sqrt( 1.e0 - min( x*x, 1.e0 ) )
share|improve this answer
    
Except the domain of cosine is [-1.0, 1.0], which should, when squared, result in a domain of [0.0, 1.0]. There should be no possibility of a negative argument to the function. – Ignacio Vazquez-Abrams Dec 5 '13 at 13:28
    
Mark is right. Also for integer valued real variables the arithmetic is usually exact. – Vladimir F Dec 5 '13 at 13:36

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