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I'm trying to understand how floating point numbers work.

I think I'd like to test out what I know / need to learn by evaluating the following: I would like to find the smallest x such that x + 1 = x, where x is a floating point number.

As I understand it, this would happen in the case where x is large enough so that x + 1 is closer to x than the next number higher than x representable by floating point. So intuitively it seems it would be the case where I don't have enough digits in the significand. Would this number x then be the number where the significand is all 1's. But then I can't seem to figure out what the exponent would have to be. Obviously it would have to be big (relative to 10^0, anyway).

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2  
As you ask it, minus infinity :-) You probably want the smallest positive number and not the smallest number. –  AProgrammer May 3 '10 at 9:16

3 Answers 3

up vote 5 down vote accepted

You just need an expression for the value of the LS bit in the mantissa in terms of the exponent. When this is > 1 then you have met your condition. For a single precision float the LS bit has a value of 2^-24*2^exp, so the condition would me met when exp is > 24, i.e. 25. The smallest (normalized) number where this condition would be satisfied would therefore be 1.0 * 2^25 = 33554432.0f.

I haven't checked this, so my maths may be off somewhere (e.g. by a factor of 2) and it's also possible that the FP unit does rounding beyond the 24th bit, so there may be a further factor of 2 needed to account for this, but you get the general idea...

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oh man, i literally figured it out RIGHT as you posted this! Nice! –  NMoney May 3 '10 at 9:06
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Actually, x=2^24 is the first float to meet the condition (anything greater than 2^24 - 1 requires 25 bits, and hence more than a float can hold exactly). –  Rick Regan May 3 '10 at 12:57
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there are likely a couple of sticky bits beyond the mantissa that you dont see, used for rounding so depending on how the number makes it into the register (through an int to float or through float + float(1.0), etc) can have subtle differences, so it could be 24 or 25 or 26 bits but somewhere in that range you push that one off the end of the mantissa into the ether. –  dwelch May 3 '10 at 14:07
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@dwelch: I'm pretty sure it will happen in the 25 bit range; if not for 2^24 (it works for 2^24 in my test), soon thereafter. 25-bit integers have to be rounded to even numbers (16777216, 16777218, 16777220, 16777222, ...), so those are the candidates for x. You would have to be more than unlucky for all 2^23 of those -- each added to 1 -- to round away from x! –  Rick Regan May 3 '10 at 16:07
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I would assume some fpus vary in this regard, I have not looked at the spec in a long time to see if it has details on this. From a theoretical perspective you need at least one more bit there to do the rounding. To answer the specific question also depends on the X and rounding 1 plus the right number will round into the mantiss and other rounding modes wont. Perhaps we have beaten this horse to death and the poster understands the exponent mantissa thing wellenough. –  dwelch May 3 '10 at 20:08

Start with 1.0, and keep doubling it until the test succeeds:

double x;
for (x = 1.0; x + 1 != x; x *= 2) { }
printf("%g + 1 = %g\n", x, x + 1);
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trying it out doesn't mean i understand why :) i'd kind of prefer to reason it out first. i guess this post is more generally about how rounding is incorporated into floating point math, as evidenced by the sample question i propose. –  NMoney May 3 '10 at 8:51

I suggest that while trying to understand f-p numbers and f-p arithmetic you work in decimal with 5 digits in the significand and 2 in the exponent. (Or, if 5 and 2 don't suit you, 6 and 3 or any other small numbers you like.) The issues of:

  • the limited set of numbers which can be represented;
  • non-commutativity, non-associativity and non-distributivity;
  • the problems which can arise when treating f-p numbers as real numbers;

are all much easier to figure out in decimal and the lessons you learn are entirely general. Once you've got this figured out, enhancing your knowledge with IEEE f-p arithmetic will be relatively straightforward. You'll also be able to figure out other f-p arithmetic systems with relative ease.

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