Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them; it only takes a minute:

While working on a simple programming exercise, I produced a while loop (DO loop in Fortran) that was meant to exit when a real variable had reached a precise value.

I noticed that due to the precision being used, the equality was never met and the loop became infinite. This is, of course, not unheard of and one is advised that, rather than comparing two numbers for equality, it is best see if the absolute difference between two numbers is less than a set threshold.

What I found disappointing was how low I had to set this threshold, even with variables at double precision, for my loop to exit properly. Furthermore, when I rewrote a "distilled" version of this loop in Perl, I had no problems with numerical accuracy and the loop exited fine.

Since the code to produce the problem is so small, in both Perl and Fortran, I'd like to reproduce it here in case I am glossing over an important detail:

Fortran Code

PROGRAM precision_test

! Data Dictionary
INTEGER :: count = 0 ! Number of times the loop has iterated
REAL(KIND=8) :: velocity

velocity = 0.5 * MACH_2_METERS_PER_SEC ! Initial Velocity
        WRITE (*, 300) velocity
        300 FORMAT (F20.8)
        IF (count == 50) EXIT
        IF (velocity == 5.0 * MACH_2_METERS_PER_SEC) EXIT
!       IF (abs(velocity - (5.0 * MACH_2_METERS_PER_SEC)) < 1E-4) EXIT
        velocity = velocity + 0.1 * MACH_2_METERS_PER_SEC
        count = count + 1 

END PROGRAM precision_test

Perl Code

#! /usr/bin/perl -w
use strict;

my $mach_2_meters_per_sec = 340.0;

my $velocity = 0.5 * $mach_2_meters_per_sec;

while (1) {
        printf "%20.8f\n", $velocity;   
        exit if ($velocity == 5.0 * $mach_2_meters_per_sec);
        $velocity = $velocity + 0.1 * $mach_2_meters_per_sec;

The commented-out line in Fortran is what I would need to use for the loop to exit normally. Notice that the threshold is set to 1E-4, which I feel is quite pathetic.

The names of the variables come from the self-study-based programming exercise I was performing and don't have any relevance.

The intent is that the loop stops when the velocity variable reaches 1700.

Here are the truncated outputs:

Perl Output




Fortran Output




What good is Fortran's speed and ease of parallelization if its accuracy stinks? Reminds me of the three ways to do things:

  1. The Right Way

  2. The Wrong Way

  3. The Max Power Way

"Isn't that just the wrong way?"

"Yeah! But faster!"

All kidding aside, I must be doing something wrong.

Does Fortran have inherent limitations on numerical accuracy compared to other languages, or am I (quite likely) the one at fault?

My compiler is gfortran (gcc version 4.1.2), Perl v5.12.1, on a Dual Core AMD Opteron @ 1 GHZ.

share|improve this question
Shouldn't #3 be "The Max Power way"? – detly Jul 26 '10 at 2:09
Whoops. You're right. Thanks! – EMiller Jul 26 '10 at 2:16
Fortran is using a double here and I suspect Perl to do the same. But checking for an equal with a floating point number is asking for problems (unless you have a "safe" number like 0.0144). So I would say that it is probably your method of testing that is wrong. – Wolph Jul 26 '10 at 2:23
This is a very interesting problem. I ran your Fortran code and got the same results. My first instinct was to suspect a base-2 conversion error in FORTRAN, but if so why isn't Perl susceptible to it? FORTRAN and Perl both implement IEEE-754. Also, a double precision number should only succumb to rounding errors in the 15-16 digit, but in your Fortran printout, the rounding error occurs much earlier. Very curious! – Gilead Jul 26 '10 at 2:33
@Gilead: Yes, I thought the same thing initially, regarding the rounding error being in the 15-16 digit and so I assumed that, at worst, the repeated multiplications were compounding the error dramatically by the time I reached ~1700. It wasn't until I printed out the entire sequence of values, from the initial value to what would have been the stopping point, that I saw that the rounding error was of far greater magnitude then E-15 even after the first multiplication. In any case, thank you for the comments. – EMiller Jul 27 '10 at 1:50

2 Answers 2

up vote 15 down vote accepted

Your assignment is accidentally converting the value to single precision and then back to double.

Try making your 0.1 * be 0.1D0 * and you should see your problem fixed.

share|improve this answer
Actually, he was using a REAL(kind=8), which is DOUBLE PRECISION. – Gilead Jul 26 '10 at 2:30
@Gilead: Yes, I missed that initially; my Fortran experience isn't with GNU Fortran. Removed bad answer and put in correct answer. – ysth Jul 26 '10 at 2:43
Ah! That's the answer. Very subtle! +1 for this. – Gilead Jul 26 '10 at 3:03
@CmdrGuard: yes, but the single precision value closest to .1 is a lot more inaccurate than the double precision value closest to .1. For example, the 0.1 in the following is promoted to double, but that doesn't magic back the lost precision: WRITE (*, "(F20.18)") (0.1-0.1D0) – ysth Jul 28 '10 at 1:55
The order is key: the decimal constant "0.1" is converted to binary representation using single precision. The conversion to single-precision binary will involve more of the base-conversion issues than if the conversion were to double-precision binary, which would be done if the constant were written "0.1D0" or "0.1_DR_K" in my example. Then when that single-precision binary value is used in an expression with a double-precision variable, it is converted to double precision and the entire calculation is done in double precision. But the base conversion already was done in single! – M. S. B. Jul 28 '10 at 2:04

As already answered, "plain" floating point constants in Fortran will default to the default real type, which will likely be single-precision. This is an almost classic mistake.

Also, using "kind=8" is not portable -- it will give you double precision with gfortran, but not with some other compilers. The safe, portable way to specify precisions for both variables and constants in Fortran >= 90 is to use the intrinsic functions, and request the precision that you need. Then specify "kinds" on the constants where precision is important. A convenient method is to define your own symbols. For example:

integer, parameter :: DR_K = selected_real_kind (14)


real (DR_K) :: mass, velocity, energy

energy = 0.5_DR_K * mass * velocity**2

This can also be important for integers, e.g., if large values are needed. For related questions for integers, see and

share|improve this answer
real(kind=8) is perfectly standard Fortran 90. All Fortran 90 compliant compilers should, and do, support it. That said, the proper way to ask for a given precision in Fortran 90 is something like the following: integer, parameter :: dp = selected_real_kind(15, 307) real(kind=dp) :: a See the Fortran Wiki – fB. Jul 26 '10 at 7:40
@fB: @MSB is correct to assert that kind=8 is not portable, and you are right to state that it is standard Fortran 90. The non-portability of the statement arises because while kind=8 is a valid kind selector the intepretation of the 8 is implementation dependent. Certainly most current compilers will (I believe) interpret this to be an 8-byte integer, but this is not guaranteed by the standard. It's certainly not always been true that all Fortran compilers would interpret this the same way, and one of the concerns of the average Fortran programmer is portability across time. – High Performance Mark Jul 26 '10 at 8:36
@MSB Right you are, I actually commented the wrong answer. – fB. Jul 26 '10 at 10:45
Yeah, I realize I did use a less than ideal means to declare precision. I did so more for simplicity than anything else. Perhaps I should change it to make my example code portable to readers of Stack Overflow, but since this question could affect other beginners to Fortran, maybe it's best I leave the code in the current form. – EMiller Jul 27 '10 at 1:56
@High Performance Mark - correct. There was some discussion about this in the standard committee, and it is general conclusion that integer kind numbers are often misleading as shown. For (i.e. kind=8) - 8 means nothing in particular; it is simply a number describing the implemented precision. It could've easily been 32 or 112 - just a label. The part which is important is verifying whether the processor supports your desired precision (cpu+compiler) and using it with a combination of sel...real_kind and a declaration of a varible with that type. – Rook Aug 13 '10 at 21:18

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.