# Making C floats precise?

In C, when a float is set,

int main(int argc, char *argv[]) {
float temp = 98.6f;
printf("%f\n", temp);
return 0;
}

It always seems to get some kind of rounding error,

98.599998

But when I make it more precise,

float temp = 96.600000f;

It still prints a different number. How is this supposed to be solved?

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Also see fixed-point arithmetic - not to replace floats in general, but it's another approach to some problems. –  user2246674 Jul 18 at 21:08
Another good reference: floating-point-gui.de –  abelenky Jul 18 at 21:13
If you think that is bad, how you compile your code can also change these things. Specifically it might use 80bits or 64bits for the double representation. –  Mikhail Jul 18 at 21:17

It still prints a different number. How is this supposed to be solved?

By using a different data type, if you want precise decimal values.

Binary floating point numbers are precise - it's just they're precise binary values.

Likewise decimal is imprecise if you want to represent numbers in base 3, for example. There's no exact binary representation of 0.1 decimal, just as there's no exact decimal representation of "one third".

It's all a matter of working out what your requirements are, and using a data type which matches them. For precise decimal values, you're probably best off using a third-party library... or keep an integer that you know is logically scaled by 100, or 10,000 or whatever.

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@tkbx: Yes. Except that the value is represented as two integers - a mantissa and an exponent. You might find it useful to read my article on binary floating point numbers in .NET - it's at least very similar to what you'll find in C. csharpindepth.com/Articles/General/FloatingPoint.aspx –  Jon Skeet Jul 18 at 21:17
@JonSkeet - Floating point numbers is akin to scientific notation. i.e. the numbers in the mantissa range between -10 and +10 (with the fractions in between) RAISED TO THE POWER OF 10 to the exponent. How would you write down PI in a limited number of digits and using the same space (squares on a sheet of graph paper) the speed of light. –  Ed Heal Jul 18 at 21:40
@JonSkeet - You can think of a byte as a character, yes/no, integer, whatever. At the endof the day it is a series of ons and offs. The semantics of this is up to up. Is it a letter, number, pixel, .... But in this context the mantissa is interpreted (understood) as contained the fraction part - along with sigh/NaN etc) and the exponent is understood to be a integer. But they are just bytes - series of ons and offs. –  Ed Heal Jul 18 at 21:48
@EdHeal: No, both are considered integers (at least in IEEE754), and the mantissa is shifted left or right based on the exponent (which is often offset itself). Again, please read the wikipedia article - or my own article linked in the fourth comment. Saying "the semantics of this are up to you" is just avoiding being precise about communication - semantics are everything. –  Jon Skeet Jul 18 at 21:51
IEEE 754-2008 generally treats the significand (not mantissa; mantissas are logarithmic, significands are linear) as a digit string of the form “d[0].d[1]d[2]…d[p-1]” (where subscripts would be used if the typography were available in a comment), per IEEE 754-2008 clause 3.3. Naturally, there is a mathematically equivalent formulation where the significand is always an integer, and that may be more useful for various proofs. –  Eric Postpischil Jul 19 at 13:41

This is a fundamental limitation of representing decimal numbers in binary form. Binary floating point numbers are expressed in powers of 2 while decimal numbers are expressed in powers of 10, and C's float is simply unable to exactly represent all the decimal numbers.

Your example number, 96.1 can be written as:

96.1 = 9*10^1 + 9*10^0 + 1*10^-1

To represent this in binary, you can get the integer 96 just fine:

96 = 1*2^6 + 1*2^5

but representing the 0.1 is problematic in base 2. The place values of the first few fractional places in binary are:

2^-1 = 0.5
2^-2 = 0.25
2^-3 = 0.125
2^-4 = 0.0625
2^-5 = 0.03125
2^-6 = 0.015625
2^-7 = 0.0078125
2^-8 = 0.00390625
2^-9 = 0.001953125
... and so on

So somehow you need to use a combination of these place values to add up to approximate 0.1 in decimal. So you would have to start with b0.0001 (d0.0625) as being the first place less than d0.1 and add some more of the smaller place values to get closer and closer to 0.1. For example:

b0.001      = d0.125      // too high, try lower
b0.0001     = d0.0625     // too low, so add smaller places
b0.00011    = d0.09375    // good, closer... rounding error is 0.0625
b0.000111   = d0.109375   // oops, a little high
b0.00011001 = d0.09765625 // getting better - how close do you need?
...

And so on - you get the idea. So the binary values can only approximate decimals due to the fundamental representation.

There are many articles on floating point rounding errors and representational limits. It is definitely worth doing some background reading on this topic.

There are a few ways to solve this problem:

• Use float but remain aware of the limitations and carefully design the algorithm to minimise rounding errors
• Use an exact decimal representation such as BCD (binary coded decimal), which is used in financial systems to avoid rounding errors
• Use a fixed data type, where numbers are expressed as fractions of integers, and only convert to floating point at the end of the calculation to display the result.
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Binary floating point numbers are expressed in powers of two. It's entirely feasible to have non-binary floating point numbers - the idea of a floating point number is just that there's a mantissa and an exponent, which is interpreted in some base. For example, System.Decimal in .NET is a decimal floating point number. –  Jon Skeet Jul 18 at 21:13

Adding trailing zeroes will never make a difference.

The problem is that 32-bit floating cannot precisely express 96.6, period.

It isn't randomly picking digits to fill what you left out; it's rounding it to the closest number that it can express.

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It's platform-dependent, but usually a number like 98.6 can't be represented exactly.

What you can do is use printf precision specifiers like "%.2f" to "round" the number displayed.

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+1 for "usually a number like 98.6 can't be represented exactly". Floating point could be decimal and 98.6 would then be exact. e. g. IEEE 754 decimal32. –  chux Jul 18 at 22:26

There's no simple answer. It has to do with how floats are represented in memory, but how we tend to think they can represent all real numbers. They can't. If you want to be precise with floats, think of less-than or greater-than ranges instead of trying to equate them. In your example, try %f2.1 (or similar) to print out a smaller amount of digits to the right of the decimal place.

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The give away is the word float.

It is composed of a mantissa and an exponent. The value is the best representation that it can achieve in a limited number of bits (take pi for example).

So do not use equality as you get rounding errors. You can take steps to minimise them, but that requires a few lectures and a text book.

BTW - Do not use floats for money. Better use integers and compute things in cents/pennies/...

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Your answer doesn't explain why "98.6" can't be represented exactly. The key problem here isn't that it's floating point - it's that the point being floated is a binary point, whereas the source data is decimal. –  Jon Skeet Jul 18 at 21:14