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This is one interview question. How do you compute the number of digit after . in floating point number.

e.g. if given 3.554 output=3

for 43.000 output=0. My code snippet is here

double no =3.44;
int count =0;
while(no!=((int)no))
{
    count++;
    no=no*10;
}
printf("%d",count);

There are some numbers that can not be indicated by float type. for example, there is no 73.487 in float type, the number indicated by float in c is 73.486999999999995 to approximate it.

Now how to solve it as it is going in some infinite loop.

Note : In the IEEE 754 Specifications, a 32 bit float is divided as 24+7+1 bits. The 7 bits indicate the mantissa.

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3  
So what should it do when you pass a non-ending decimal number to it? Should the program somehow know that 73.486999999999995 is "actually" 73.487? Are you sure the decimal number should be a float, not a string representation? –  Juhana Jul 24 '13 at 14:59
2  
@Juhana: Assuming binary floating-point, all representable numbers are multiples of some power of two; no infinitely repeating rational numbers are representable. –  Keith Thompson Jul 24 '13 at 15:01
    
@Juhana...if I give 73.487 it is going in infinite loop. I am not sure if I declare it as double and somehow it is converting to string. But why it should be a string representation? –  someone Jul 24 '13 at 15:02
    
@Juhana The way to know it is that the floating point representations of both numbers are the same. So you want the shortest fraction that results in the same floating point. –  Barmar Jul 24 '13 at 15:04
4  
@LS_dev: The result for 2.00000 (which is exactly representable) is simply 0. And a question isn't stupid just because the answer happens to be "you can't do that". It's a good question if the OP and other readers learn something from it. –  Keith Thompson Jul 24 '13 at 15:28

6 Answers 6

up vote 2 down vote accepted

The problem isn't really solvable as stated, since floating-point is typically represented in binary, not in decimal. As you say, many (in fact most) decimal numbers are not exactly representable in floating-point.

On the other hand, all numbers that are exactly representable in binary floating-point are decimals with a finite number of digits -- but that's not particularly useful if you want a result of 2 for 3.44.

When I run your code snippet, it says that 3.44 has 2 digits after the decimal point -- because 3.44 * 10.0 * 10.0 just happens to yield exactly 344.0. That might not happen for another number like, say, 3.43 (I haven't tried it).

When I try it with 1.0/3.0, it goes into an infinite loop. Adding some printfs shows that no becomes exactly 33333333333333324.0 after 17 iterations -- but that number is too big to be represented as an int (at least on my system), and converting it to int has undefined behavior.

And for large numbers, repeatedly multiplying by 10 will inevitably give you a floating-point overflow. There are ways to avoid that, but they don't solve the other problems.

If you store the value 3.44 in a double object, the actual value stored (at least on my system) is exactly 3.439999999999999946709294817992486059665679931640625, which has 51 decimal digits in its fractional part. Suppose you really want to compute the number of decimal digits after the point in 3.439999999999999946709294817992486059665679931640625. Since 3.44 and 3.439999999999999946709294817992486059665679931640625 are effectively the same number, there's no way for any C function to distinguish between them and know whether it should return 2 or 51 (or 50 if you meant 3.43999999999999994670929481799248605966567993164062, or ...).

You could probably detect that the stored value is "close enough" to 3.44, but that makes it a much more complex problem -- and it loses the ability to determine the number of decimal digits in the fractional part of 3.439999999999999946709294817992486059665679931640625.

The question is meaningful only if the number you're given is stored in some format that can actually represent decimal fractions (such as a string), or if you add some complex requirement for determining which decimal fraction a given binary approximation is meant to represent.

There's probably a reasonable way to do the latter by looking for the unique decimal fraction whose nearest approximation in the given floating-point type is the given binary floating-point number.

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I doubt this is what you want since the question is asking for something that's not usually meaningful with floating point numbers, but here is the answer:

int digits_after_decimal_point(double x)
{
    int i;
    for (i=0; x!=rint(x); x+=x, i++);
    return i;
}
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2  
You're doubling x on each iteration. Wouldn't that give you the number of binary digits rather than decimal? –  Keith Thompson Jul 24 '13 at 15:06
2  
@KeithThompson: The number of decimal digits after the decimal point is equal to the number of binary digits after the decimal point. –  R.. Jul 24 '13 at 15:09
    
By the way the alternate version was buggy so I removed it (it didn't count mantissa bits). It could be fixed, but once it gets complicated it's not very informative. –  R.. Jul 24 '13 at 15:10
    
Simple examples: 1/2 = 0.5 (1 digit either way), 1/32 = 0.03125 (5 digits either way), ... –  R.. Jul 24 '13 at 15:14
1  
@KeithThompson: Yes, I addressed the fact that it's probably not what OP wants in the opening of my answer. :-) –  R.. Jul 24 '13 at 16:11

Sounds like you need to either use sprintf to get an actual rounded version, or have the input be a string (and not parsed to a float).

Either way, once you have a string version of the number, counting characters after the decimal should be trivial.

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The question could be interpreted as such:

Given a floating point number, find the shortest decimal representation that would be re-interpreted as the same floating point value with correct rounding.

Once formulated like this, the answer is Yes we can - see this algorithm:

Printing floating point numbers quickly and accurately. Robert G. Burger and R. Kent Dybvig. ACM SIGPLAN 1996 Conference on Programming Language Design and Implementation, June 1996

http://www.cs.indiana.edu/~dyb/pubs/FP-Printing-PLDI96.pdf

See also references from Compute the double value nearest preferred decimal result for a Smalltalk implementation.

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Does the use of intermediate types in floating-point parsing confuse things? In many .net languages, for example, attempting to parse the value 9007199791611905 as a float will not yield the closest float because it will first be converted to double (rounding it down to the next even integer), and that will then be rounded down again. I wonder if there are any float values whose shortest decimal representation would be correct if converted directly to float, but would yield incorrect results if parsed via double? –  supercat Jul 25 '13 at 17:03
    
@supercat very difficult question... With many digits like your example, yes, we can build numbers such that rounding twice leads to a different float like stackoverflow.com/questions/13276862/… but starting with minimal number of decimal digits for a Float, such number is not obvious to build. Does it even exists? –  aka.nice Jul 25 '13 at 21:47
    
The particular number I mentioned is the smallest whole number for which which conversion via double yields something other than the closest float. I don't know of any particular minimal-length float values where double-rounding would cause trouble; I was wondering whether you either knew of any or knew with certainty that none exist. –  supercat Jul 25 '13 at 22:08
1  
@supercat After launching some loops, here's the smallest I found: 7.038531e-26f will produce a sequence of bits that rounds twice upper as in my example. –  aka.nice Jul 26 '13 at 19:20
    
That would indeed seem to represent a problem case. That value, cast to double, then float, then double, is 0.0000003081487913E-26 higher than the original specified numeric quantity; the next lower float would be 0.0000003081487909 lower than original specified numeric quantity [i.e. it's a smidgin closer]. Which of those two float values would be printed as 7.038531e-26 by the linked algorithm? –  supercat Jul 26 '13 at 20:12

There's no general exact solution. But you can stop after exceeding the current type's precision so that it won't run infinitely. Also, you can count if there are continuous 0s or 9s and exclude them. This will make it runs fine for more cases but it still don't return the correct answer for all.

For example double's accuracy is about 16-17 digits, so for 73.486999999999995 you can run 17 - 2 (minus the 2 digits in the int part) times. After that, except for the last digit, there are many 9s so subtract them from the count too

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What you can do is multiply the number by various powers of 10, round that to the nearest integer, and then divide by the same number of powers of 10. When the final result compares different from the original number, you've gone one digit too far.

I haven't read it in a long time, so I don't know how it relates to this idea, but How to Print Floating-Point Numbers Accurately from PLDI 1990 and 2003 Retrospective are probably very relevant to the basic problem.

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I think I am doing that only...Is there any change what you said and what I did? –  someone Jul 24 '13 at 15:08
1  
Among other problems, if the input is the double nearest 1/3, this algorithm returns 16. Why? The double nearest 1/3 has 54 digits after the decimal point; it is 0.333333333333333314829616256247390992939472198486328125. It is not even close to a 16-digit decimal numeral (that is, its deviation from the nearest 16-digit decimal numeral is much larger than the value of a digit at that position). –  Eric Postpischil Jul 24 '13 at 15:48
    
@EricPostpischil The input isn't a fraction like 1/3, it's something that's already a decimal like 0.33345. When this gets converted to a double, it might be something like 0.333459999...125. The goal is merely to determine that 0.33345 is a shorter decimal that will produce the same double. –  Barmar Jul 24 '13 at 16:28
    
I've added links to some papers on printing of floating point numbers that discuss these ideas. –  Barmar Jul 24 '13 at 16:36
1  
@Barmar: If you are given a string and want to know the number of digits after the decimal point, then you should not parse it as a float at all. Just directly count the digits in the string. –  Eric Postpischil Jul 24 '13 at 16:50

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