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Let's say I have two floating point numbers, and I want to compare them. If one is greater than the other, the program should take one fork. If the opposite is true, it should take another path. And it should do the same thing, if the value being compared is nudged very slightly in a direction that should still make it compare true.

It's a difficult question to phrase, so I wrote this to demonstrate it -

float a = random();
float b = random();  // always returns a number (no infinity or NaNs)

if(a < b){
    if( !(a < b + FLOAT_EPISILON) ) launchTheMissiles();

}else if(a >= b){
    if( !(a >= b - FLOAT_EPISILON) ) launchTheMissiles();

    launchTheMissiles();  // This should never be called, in any branch

Given this code, is launchTheMissiles() guaranteed to never be called?

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@Clairvoire: I see no guarantee that b + FLOAT_EPISILON isn't infinity, which may cause missiles. –  Mooing Duck Mar 12 '13 at 23:49
What is FLOAT_EPISILON? Do you mean FLT_EPSILON, defined in <float.h> or <cfloat>? –  Keith Thompson Mar 12 '13 at 23:52
It's poor style, and sometimes dangerous, to compare boolean values for equality to true or false. x > y is already a condition. If you want to negate it, use the ! operator. –  Keith Thompson Mar 12 '13 at 23:53
You may have been deceived by the "always compare floats with epsilon"-rubbish going around, but no, launchTheMissles can never ever be called (well, except for NaNs). –  Christian Rau Mar 13 '13 at 8:29

4 Answers 4

up vote 6 down vote accepted

If you can guarantee that a and b are not NaNs or infinities, then you can just do:

if (a<b) {
} else {

The set of all floating point values except for infinities and NaNs comprise a total ordering (with a glitch with two representations of zero, but that shouldn't matter for you), which is not unlike working with normal set of integers — the only difference is that the magnitude of intervals between subsequent values is not constant, like it is with integers.

In fact, the IEEE 754 has been designed so that comparisons of non-NaN non-infinity values of the same sign can be done with the same operations as normal integers (again, with a glitch with zero). So, in this specific case, you can think of these numbers as of “better integers”.

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Can you explain the 'glitch with zero'? Does it cause any 'gotchas'? –  Patashu Mar 13 '13 at 0:00
Zero has two possible representations in floating point notation. Both of them set significand and exponent fields to zero; one of them sets the sign to positive, the other to negative. Both of these encodings results in the same number, mathematically. The simplest thing you can do to keep things working is just to detect one of these cases and convert it to the other one during the comparison. The FPU will do that for you. –  liori Mar 13 '13 at 0:04

Short answer, it is guaranteed never to be called.

If a<b then a will always be less than b plus a positive amount, however small. In which case, testing if a is less than b + an amount will be true.

The third case won't get reached.

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lol I was in the middle of typing the same answer! –  Lorkenpeist Mar 12 '13 at 23:54
I accidentally downvoted you. Can you edit the post to remove the vote block ? –  Thorsten S. Mar 13 '13 at 15:25

Tests for inequality are exact, as are tests for equality. People get confused because they don't realize that the values they are working with might not be exactly what they think they are. So, yes, the comment on the final function call is correct. That branch will never be taken.

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I accidentally downvoted you. Can you edit the post to remove the vote block ? –  Thorsten S. Mar 13 '13 at 15:25
@ThorstenS. - done. –  Pete Becker Mar 13 '13 at 15:54

The IEEE 754 (floating point) standard states that addition or subtraction can result in a positive or negative infinity, so b + FLOAT_EPSILON and b - FLOAT_EPSILON can result in positive or negative infinity if b is FLT_MAX or -FLT_MAX. The floating point standard also states that infinity compares as you would expect, with FLT_MAX < +infinity returning true and -FLT_MAX > -infinity.

For a closer look at the floating point format and precision issues from a practical standpoint, I recommend taking a look at Christer Ericson's book Real Time Collision Detection or Bruce Dawson's blog posts on the subject, the latest of which (with a nice table of contents!) is at http://randomascii.wordpress.com/2013/02/07/float-precision-revisited-nine-digit-float-portability/.

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I accidentally downvoted you. Can you edit the post to remove the vote block ? –  Thorsten S. Mar 13 '13 at 15:24
@ThorstenS. Done –  masrtis Mar 13 '13 at 17:41
It's worthwhile to note that when if x and y are real numeric quantities, xf is the best float representation of x, and yd is the best double representation of y, xf > (float)yd will only be true if x is either greater than y or very close to it (within half an LSB of a double), but (double)xf > yd may be true even if y is hundreds of orders of magnitude greater than x. –  supercat Jun 13 '13 at 22:03

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