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I need to convert a floating-point number with system precision to one with a specified precision (e.g. 3 decimal places) for the printed output. The fprintf function will not suffice for this as it will not correctly round some numbers. All the other solutions I've tried fail in that they all reintroduce undesired precision when I convert back to a float. For example:

float xf_round1_f(float input, int prec) {

    int trunc = round(input * pow(10, prec));
    input=(float)trunc / pow(10, prec);
    return (input);


This function prints the input, the truncated integer and the output to each line, and the result looks like this for some numbers supposed to be truncated to 3 decimal places:

49.975002 49975.000000 49.974998

49.980000 49980.000000 49.980000

49.985001 49985.000000 49.985001

49.990002 49990.000000 49.990002

49.995003 49995.000000 49.994999

50.000000 50000.000000 50.000000

You can see that the second step works as intended - even when "trunc" is cast to float for printing - but as soon as I convert it back to a float the precision returns. The 1st and 6th rows illustrate problem cases.

Surely there must be a way of resolving this - even if the 1st row result remained 49.975002 a formatted print would give the desired effect, but in this case there is a real problem.

Any solutions?

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floating-point-gui.de –  Oliver Charlesworth Oct 2 '13 at 19:07
This is unavoidable with binary floating point, sorry. –  Mark Ransom Oct 2 '13 at 19:08
@Eric Sorry deleted it as soon as posted since it also didn't answer the question :-). –  podperson Oct 2 '13 at 19:10
Usually the approach in such cases -- often for example for currency amounts, is to use an integer type and convert it to fixed precision for display purposes. E.g. for currency you might use int32_t cents. Some programming languages (e.g. COBOL) have specific types to deal with this issue. The fundamental problem is that 5 does not go into 2 in much the same way that 3 does not go into 10, so any decimal number is an infinitely recurring expansion in binary. –  podperson Oct 2 '13 at 19:12
@JWDN: Your question was likely voted down because you still have not specified the problem precisely, you are not using floating-point correctly, and you probably should not be using it. There are alternative ways to do arithmetic if you want to preserve decimal digits. Floating point was designed for mathematical, scientific, and engineering calculations, with large dynamic range and good mathematical properties for those purposes. You are using it for a different purpose than it was designed for, so of course you are having problems. The answer you accepted is a kludge. –  Eric Postpischil Oct 2 '13 at 22:20

4 Answers 4

up vote 1 down vote accepted

Edit: it appears you may only care about the printed results. printf is generally smart enough to do proper rounding to the number of digits you specify. If you give a format of "%.3f" you will probably get what you need.

If your only problem is with the cases that are below the desired number, you can easily fix it by making everything higher than the desired number instead. Unfortunately this increases the absolute error of the answer; even a result that was exact before, such as 50.000 is now off.

Simply add this line to the end of the function:

input=nextafterf(input, input*1.0001);

See it in action at http://ideone.com/iHNTzs

49.975002   49975.000000    49.974998   49.975002
49.980000   49980.000000    49.980000   49.980003
49.985001   49985.000000    49.985001   49.985004
49.990002   49990.000000    49.990002   49.990005
49.995003   49995.000000    49.994999   49.995003
50.000000   50000.000000    50.000000   50.000004
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I'd like to say thank you, first for revealing that my long-held assumption that printf ALWAYS truncated numbers appears to incorrect - is this platform-dependent?. Second, even if printf DID behave the way I had assumed, this solution would solve the problem. –  JWDN Oct 2 '13 at 19:55
@JWDN, if 7.895f actually becomes 7.89499999 then it's not going to round to two decimal places the way you expect. To fix my formula for both positive and negative numbers, use nextafterf(input, 1.1*input). –  Mark Ransom Oct 2 '13 at 20:32
@JWDN re platform-dependent printf: you might find my article exploringbinary.com/… a good read. –  Rick Regan Oct 3 '13 at 1:31
Another drawback of nextafterf(input, input+1.0) is that it may produce unexpected results for values of input such that input == input+1.0. copysignf(FLT_MAX, input) is a better second argument to nextafterf(). –  Pascal Cuoq Oct 3 '13 at 3:12
@PascalCuoq, very good point. I've modified my answer, although your suggestion might be even better. –  Mark Ransom Oct 3 '13 at 3:15

Fixed point numbers. That is where you keep the actual numbers in a wide precision integer format, for example long or long long. And you also keep the number of decimal places. And then you will also need methods to scale the fixed point number by the decimal places. And some way to convert to/from strings.

The reason why you are having trouble that 1/10 is not representable exactly as a fractional power of 2 (1/2, 1/4, 1/8, etc). This is the same reason that 1/3 is a repeating decimal in base 10 (0.33333...).

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If you require exact representation of all decimal fractions with three digits after the decimal point, you can work in thousandths. Use an integer data type to represent one thousand times the actual number for all intermediate results.

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Binary floating-point cannot represent most decimal numerals exactly. Each binary floating-point number is formed by multiplying an integer by a power of two. For the common implementation of float, IEEE-754 32-bit binary floating-point, that integer must be in (–224, 224). There is no integer x and integer y such that x•2y exactly equals 49.975. Therefore, when you divide 49975 by 1000, the result must be an approximation.

If you merely need to format a number for output, you can do this with the usual fprintf format specifiers. If you need to compute exactly with such numbers, you may be able to do it by scaling them to representable values and doing the arithmetic either in floating-point or in integer arithmetic, depending on your needs.

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I do appreciate this, but surely I don't have to resort to converting each number to a string, evaluating each digit after the decimal and converting back into a number? I was hoping to avoid this (and I'm not even sure it would work). –  JWDN Oct 2 '13 at 19:15
@JWDN: You seem to have missed the point. You cannot convert back to a number (a float) and get 49.975 exactly. The method used to do the rounding is irrelevant. There is no value of a float that is exactly 49.975. No matter what bits you put into a float, it will never have exactly the value 49.975. The values in your examples that appear to be correct are illusions, other than 50; they appear that way only because you have printed a limit number of digits. –  Eric Postpischil Oct 2 '13 at 19:16
Honestly I DO understand this. But I'm not the first person to come up against this, and for many applications it is not acceptable - so I am still (perhaps vainly) hoping for a solution. –  JWDN Oct 2 '13 at 19:19
@JWDN: The solution is to not use a binary floating-point datatype. –  Oliver Charlesworth Oct 2 '13 at 19:22
@JWDN: You have not really stated your problem yet. If your problem is “I want 49.975 in a binary floating-point object”, the answer is you are not going to get it, because it is logically impossible. However, if you explain more about the larger computation you are trying to do, there may be solutions. –  Eric Postpischil Oct 2 '13 at 19:29

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