Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Sign up and start helping → Learn more about Documentation →

I have two

double a, b;

I know that the following is true

-1 <= a/b <= 1

however b can be arbitrarily small. When I do this naively and just compute the value


the condition specified above does not hold in some cases and I get values like much greater than 1 in absolute value (like 13 or 14.)

How can I ensure that when I divide by b, I get a value such that the condition mentioned above can be enforced. In the case where I can not guarantee this I am happy to set the computed value a/b to 0.

share|improve this question
When you say that -1 <= a/b <= 1, do you mean in theory or in practice? Might you already have roundoff errors in a and/or b before you do the division? – Steve314 Oct 8 '09 at 0:55
Please provide the actual numbers you're actually using to get the actual value of 13 or 14. – S.Lott Oct 8 '09 at 1:31
Are you dealing with subnormal numbers? (en.wikipedia.org/wiki/Subnormal_number) – Jason S Oct 8 '09 at 2:55
If be can be arbitrarily small then a/b will be arbitrarily large. – Bill Oct 8 '09 at 16:29
up vote 10 down vote accepted

What you need to enforce is abs(a)≤abs(b). If that condition holds, then -1≤a/b≤1, regardless of floating-point precision used. Your logic error is occurring before the division, since at the division point abs(a)>abs(b) which violates your a-priori requirement.

share|improve this answer
absolutely correct. – Jason S Oct 8 '09 at 2:51
I think there may be a problem with a and b before I even get to this step. I'm going to have to get back to you guys. – ldog Oct 8 '09 at 3:36
Ok so if anyone cares, the actual case of my error happened before I got to the division step and the condition abs(a)<=abs(b) was being broken before division. – ldog Oct 8 '09 at 21:57

Division on an IEEE-754 system is a correctly rounded operation, which means that if no overflow or underflow occurs, the result will always be within 0.5 "ulp" of the mathematical "infinitely precise" result. In non-FP-nerd speak, this means that the result will always be within a factor of about 2^-53 of the exact answer. Since you know that the infinitely precise result is between -1 and 1, overflow cannot occur; underflow can, but that would result in numbers very, very near zero, not on the order of 13.

Either your condition does not actually hold, or you are on a system that does not have IEEE-754 arithmetic, or there is a bug in your code. Can you post the values of a and b that are generating this result, and the code that you are using to do the division and print the result?

share|improve this answer
That's not strictly true. The IEEE standard specifies a few different rounding modes, but your point is valid: division hardware (and software emulations) are accurate to within the precision available. The problem here is lack of precision of the underlying representation, not a bad algorithm. – Andy Ross Oct 8 '09 at 2:36
True. I'm assuming that a user who is (apparently) not particularly savvy about floating-point has probably not changed the rounding mode from the default. The rounding error in a non-default rounding mode can be as large as 1ulp, which is still fantastically smaller error than the error that the questioner is reporting. – Stephen Canon Oct 8 '09 at 2:48

It's very unlikely you're actually triggering data loss due to underflow. While it is possible doubles have an incredible range and you're not likely to hit it.

I would think the problem lies somewhere before this. You've either got a logic bug or you are simply eating up the available precision with a bunch of operations. Be especially wary of additions and subtractions. 1E20 + 1 = 1E20.

If it's due to eating up the precision then you'll have to redesign your routine or resort to an arbitrary-precision library for your math. (Beware--SLOW)

share|improve this answer

I am a little confused by your question, but if you are suggesting that -1 <= a/b <= 1 holds true for all real value a and b, this is definitely not the case. Consider:

1 / 0.5 = 2

If you want to check whether the division will be within [-1, 1], why not just do the division and then act however you want when it falls between -1 and 1.

share|improve this answer
No, this is true of only the particular two numbers a and b. I'm getting inaccuracies because I'm dividing by a number that is much too small, smaller than machine precision. I need a way to check when I can guarantee the result us atmost a certain value from the true result. – ldog Oct 8 '09 at 0:53
The only number smaller than machine precision is 0. If you are not dividing by 0, then you are not dividing by a number smaller than machine precision. – Sam Harwell Oct 8 '09 at 1:04
I wonder if he's talking about subnormal numbers. – Jason S Oct 8 '09 at 2:54
@280z28: yes thats right, the only number smaller is 0. – ldog Oct 8 '09 at 16:39

If you really want to test out your theory that this is a precision issue (though the other answers make it seem like you can't possibly be getting the results you're getting) you should be using GMP. You already said you're "dividing by a number that is much too small, smaller than machine precision." GMP's C++ bindings have arithmetic operators for everything and are actually kind of pleasant to use compared to the C bindings, give them a try!

      mpf_class f(1.5);        // default precision
      mpf_class f(1.5, 500);   // 500 bits of precision (at least)
      double out = f.get_d();  // get a double out of an mpf_class
share|improve this answer

The only situations I can think of where this would be true, are if a/b should be between -1 and 1, but is not, because both a and b are derived from calculations that make them very sensitive to floating-point errors.

For instance, if you try to calculate b = 2-2*cos(theta) and a = theta*theta for theta in radians, near zero, you will run into issues because the calculation of b involves the subtraction of numbers very close to 1, even though mathematically the answer is very close to 1.0 for small angles. (If I run the calculation of a/b for theta = 0.4e-7 using the Spidermonkey Javascript engine, I get 1.029 even though it really should be darned close to 1.0)

280Z28's answer is where you want to be, however without knowing more about how a and b are derived, and under what conditions you get undesirable results, it's hard to say what the best way is to ensure the calculations give meaningful numbers.

share|improve this answer

You surely have some problem before you reach this point. Regardless, you can elimate that problem here if you are prepared to accept a 0 result.

float Calculate(float a, float b)
    if (abs(a) > abs(b))
        return 0;
        return a/b;
share|improve this answer
If -1 <= a/b <= +1 is theoretically satisfied but wrong in practice due to rounding errors, the OP might want to return +1 or -1 (depending on the signs of a and b) instead of 0. – sellibitze Oct 8 '09 at 8:59

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.