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There is a example in http://www.gotw.ca/gotw/067.htm

int main()
{
  double x = 1e8;
  //float x = 1e8;
  while( x > 0 )
  {
    --x;
  }
}

When you change the double to float, it's a infinite loop in VS2008. According to the Gotw explanation:

What if float can't exactly represent all integer values from 0 to 1e8? Then the modified program will start counting down, but will eventually reach a value N which can't be represented and for which N-1 == N (due to insufficient floating-point precision)... and then the loop will stay stuck on that value until the machine on which the program is running runs out of power.

From what I understand, the IEEE754 float is a single precision(32 bits) and the range of float should be +/- 3.4e +/- 38 and it should have a 7 digits significant.

But I still don't understand how exactly this happens: "eventually reach a value N which can't be represented and for which N-1 == N (due to insufficient floating-point precision)." Can someone try to explan this bit ?

A bit of extra info : When I use double x = 1e8, it finished in about 1 sec, when I change it to float x = 1e8, it runs much longer(still running after 5 min), also if I change it to float x = 1e7;, it finished in about 1 second.

My testing environment is VS2008.

BTW I'm NOT asking the basic IEEE 754 format explanation as I already understand that.

Thanks

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1  
This floating point calculator might help your understanding. Try inputting 1<<24==16777216 and then (1<<24)+1==16777217 and see that the 32-bit floating point representation is the same. –  user786653 Aug 9 '11 at 12:30
    
I understand the IEEE 754 floating & double format, but this does not answer my question... –  Gob00st Aug 9 '11 at 12:32
2  
The range for single precision may be +/- 3.4e +/- 38 but that doesn't mean it can represent every single number in that range precisely. –  Praetorian Aug 9 '11 at 13:21
1  
Yes so x starts out as 1e8f (exactly representable in a 32-bit float), while (x > 0) is true, so the loop runs. Now the result of x-- is ALSO 1e8f since the correct result 99999999.0f is NOT exactly representable in a 32-bit float and it is rounded to the same representation as 1e8f. –  user786653 Aug 9 '11 at 13:48
1  
@Gob00st: it's important to realize that the number 1e8 is no more or no less "precise" than 99999999 or 100000001. All of those contain the same amount of "information", i.e. they need the same amount of bits to be stored exactly. –  Joachim Sauer Aug 9 '11 at 14:57

4 Answers 4

up vote 8 down vote accepted

Well, for the sake of argument, lets assume we have a processor which represents a floating point number with 7 significant decimal digits, and an mantissa with, say, 2 decimal digits. So now the number 1e8 would be stored as

1.000 000 e 08

(where the "." and "e" need not be actually stored.)

So now you want to compute "1e8 - 1". 1 is represented as

1.000 000 e 00

Now, in order to do the subtraction we first do a subtraction with infinite precision, then normalize so that the first digit before the "." is between 1 and 9, and finally round to the nearest representable value (with break on even, say). The infinite precision result of "1e8 - 1" is

0.99 999 999 e 08

or normalized

9.9 999 999 e 07

As can be seen, the infinite precision result needs one more digit in the significand than what our architecture actually provides; hence we need to round (and re-normalize) the infinitely precise result to 7 significant digits, resulting in

1.000 000 e 08

Hence you end up with "1e8 - 1 == 1e8" and your loop never terminates.

Now, in reality you're using IEEE 754 binary floats, which are a bit different, but the principle is roughly the same.

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The operation x-- is (in this case) equivalent to x = x - 1. That means the original value of x is taken, 1 is subtracted (using infinite precision, as mandated by IEEE 754-1985), and then the result is rounded to the next value of the float value space.

The rounded result for the numbers 1.0e8f + i is given for i in [-10;10] below:

 -10: 9.9999992E7     (binary +|10011001|01111101011110000011111)
  -9: 9.9999992E7     (binary +|10011001|01111101011110000011111)
  -8: 9.9999992E7     (binary +|10011001|01111101011110000011111)
  -7: 9.9999992E7     (binary +|10011001|01111101011110000011111)
  -6: 9.9999992E7     (binary +|10011001|01111101011110000011111)
  -5: 9.9999992E7     (binary +|10011001|01111101011110000011111)
  -4: 1.0E8           (binary +|10011001|01111101011110000100000)
  -3: 1.0E8           (binary +|10011001|01111101011110000100000)
  -2: 1.0E8           (binary +|10011001|01111101011110000100000)
  -1: 1.0E8           (binary +|10011001|01111101011110000100000)
   0: 1.0E8           (binary +|10011001|01111101011110000100000)
   1: 1.0E8           (binary +|10011001|01111101011110000100000)
   2: 1.0E8           (binary +|10011001|01111101011110000100000)
   3: 1.0E8           (binary +|10011001|01111101011110000100000)
   4: 1.0E8           (binary +|10011001|01111101011110000100000)
   5: 1.00000008E8    (binary +|10011001|01111101011110000100001)
   6: 1.00000008E8    (binary +|10011001|01111101011110000100001)
   7: 1.00000008E8    (binary +|10011001|01111101011110000100001)
   8: 1.00000008E8    (binary +|10011001|01111101011110000100001)
   9: 1.00000008E8    (binary +|10011001|01111101011110000100001)
  10: 1.00000008E8    (binary +|10011001|01111101011110000100001)

So you can see that 1.0e8f and 1.0e8f + 4 and some other numbers have the same representation. Since you already know the details of the IEEE 754-1985 floating point formats, you also know that the remaining digits must have been rounded away.

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What is the result of n - 1 if n - 1 and n have both identical representation due to the approximate nature of floating point numbers?

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That does not answer his question "how exactly this happen"[sic]. I.e. how can it be that a n-1 == n. –  Bart Aug 9 '11 at 12:22
    
Your answer is a general answer for floating precision,not for this particular question... –  Gob00st Aug 9 '11 at 12:30
    
@Bart: it does answer the question you point out, but not the question of "eventually reach" that the OP posed. it is indeed difficult to envision a representation where "eventually reach" is meaningful. i think i would call such a representation "perverse" :-) –  Cheers and hth. - Alf Aug 9 '11 at 12:31
    
@Alf That was my point, although perhaps poorly worded. Thanks –  Bart Aug 9 '11 at 12:35
2  
@Francesco: the formal mathematical reasoning is based on the pigeonhole principle. FLOAT_MAX > 10^38 so there are over 10^38 positive integers < FLOAT_MAX, but a IEE754 float can represent at most 2^31 possible positive values. I therefore_cannot_ map every positive integer to a float value. The 2^31 float states and the 10^38 integers are both ordered. That means one of those integers that's not mapped to a float state has a larger neighbor which is mapped. IEEE754 math dictate rounding. If this mapped integer MI is decremented, (MI-1) isn't mapped and rounded back up to MI. –  MSalters Aug 9 '11 at 14:58

Regarding "reach" a value that can't be represented, I think Herb was including the possibility of quite esoteric floating point representations.

With any ordinary floating point representations, you will either start with such value (i.e. stuck on first value), or you will be somewhere in the contiguous range of integers centered around zero that can be represented exactly, so that the countdown succeeds.

For IEEE 754 the 32-bit representation, typically float in C++, has 23 bits mantissa, while the 64-bit representation, typically double in C++, has 52 bits mantissa. This means that with double you can at least represent exactly the integers in the range -(2^52-1) ... 2^52-1. I'm not quite sure if the range can be extended with another factor of 2. I get a bit dizzy thinking about it. :-)

Cheers & hth.,

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But the starting value is a quite regular one 1e8, not a strange one... How could reducing from 1e8 --x would run out of precision ??? –  Gob00st Aug 9 '11 at 12:29
    
@Gob00st: I don't know of any floating point representation where reducing by 1, starting with an integer, could "eventually" get stuck instead of either being stuck already, or getting down to 0. I don't think such a representation exists. But if it existed it could satisfy the requirements of the C++ standard, which allow just about anything. –  Cheers and hth. - Alf Aug 9 '11 at 12:36
    
I have tried double x = 1e8, it finished in about 1 sec. But when i change it to float x = 1e8, it runs much longer(still running BTW) –  Gob00st Aug 9 '11 at 12:39
    
@Gob00st: assuming a 32-bit IEEE 754 float, the highest exactly represented integer seems to be 2^23-1, unless I'm off by a factor of 2. If it is 2^23-1, then utilizing the fact that 2^10 = 1024 ~= 1000 = 10^3, you have the value 2^23 = 2^3*K*K ~ 8*10^6. So that's where you should expect the stuckness to begin: any higher value than that, u should get stuck. :-( By the way, for ways to deal with stuckness in general, I recommend the book "Zen and the Art of Motorcycle Maintenance" by Robert M. Pirzig. Cheers, –  Cheers and hth. - Alf Aug 9 '11 at 12:44
    
Why it's the highest represented integer of float is 2^23-1 ? Shouldn't it be around 2^125 ? –  Gob00st Aug 9 '11 at 13:44

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