# Why do simple doubles like 1.82 end up being 1.819999999645634565360? [duplicate]

c++

Hey so i'm making a function to return the number of a digits in a number data type given, but i'm having some trouble with doubles.

I figure out how many digits are in it by multiplying it by like 10 billion and then taking away digits 1 by 1 until the double ends up being 0. however when putting in a double of value say .7904 i never exit the function as it keeps taking away digits which never end up being 0 as the resut of .7904 ends up being 7,903,999,988 and not 7,904,000,000.

How can i solve this problem?? Thanks =) ! oh and any other feed back on my code is WELCOME!

here's the code of my function:

``````///////////////////////     Numb_Digits()   ////////////////////////////////////////////////////
enum{DECIMALS = 10, WHOLE_NUMBS = 20, ALL = 30};
template<typename T>
unsigned long int Numb_Digits(T numb, int scope)
{
unsigned long int length= 0;
switch(scope){
case DECIMALS:      numb-= (int)numb;   numb*=10000000000; // 10 bil (10 zeros)
for(; numb != 0; length++)
numb-=((int)(numb/pow((double)10, (double)(9-length))))* pow((double)10, (double)(9-length)); break;

case WHOLE_NUMBS:   numb= (int)numb;    numb*=10000000000;
for(; numb != 0; length++)
numb-=((int)(numb/pow((double)10, (double)(9-length))))* pow((double)10, (double)(9-length)); break;

case ALL:           numb = numb;        numb*=10000000000;
for(; numb != 0; length++)
numb-=((int)(numb/pow((double)10, (double)(9-length))))* pow((double)10, (double)(9-length)); break;

default: break;}
return length;
};

int main()
{
double test = 345.6457;
cout << Numb_Digits(test, ALL) << endl;
cout << Numb_Digits(test, DECIMALS) << endl;
cout << Numb_Digits(test, WHOLE_NUMBS) << endl;

return 0;
}
``````
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## marked as duplicate by mu is too short, hammar, Tim Cooper, Joe, Jim LewisMay 15 '11 at 3:25

This is because C++ (like most other languages) can not store floating point numbers with infinte precision.

Floating points are stored like this:
`sign * coefficient * 10^exponent` if you're using base 10.
The problem is that both the `coefficient` and `exponent` are stored as finite integers.

This is a common problem with storing floating point in computer programs, you usually get a tiny rounding error.

The most common way of dealing with this is:

• Store the number as a fraction (x/y)
• Use a delta that allows small deviations (if abs(x-y) < delta)
• Use a third party library such as GMP that can store floating point with perfect precision.

There is no way of dealing with this if you get a double as input. You cannot be sure that the user actually sent 1.819999999645634565360 and not 1.82.

Either you have to change your input or change the way your function works.

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It isn't C++, it's anything directly using the FPU – Nektarios May 15 '11 at 2:59
Yes, but there are programming languages that use software calculation instead of the FPU so this is related to which language you're using. – Nicklas A. May 15 '11 at 3:03

It's because of their binary representation, which is discussed in depth here:

http://en.wikipedia.org/wiki/IEEE_754-2008

Basically, when a number can't be represented as is, an approximation is used instead.

To compare floats for equality, check if their difference is lesser than an arbitrary precision.

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The easy summary about floating point arithmetic :

http://floating-point-gui.de/

Read this and you'll see the light.

If you're more on the math side, Goldberg paper is always nice :

http://cr.yp.to/2005-590/goldberg.pdf

Long story short : real numbers are stored with a fixed, irregular precision, leading to non obvious behaviors. This is unrelated to the language but more a design choice of how to handle real numbers as a whole.

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Thanks for the easy reference. It's a nice intro. – Chris Cooper May 15 '11 at 3:06

This is because of the way the IEEE floating point standard is implemented, which will vary depending on operations. It is an approximation of precision. Never use logic of if(float == float), ever!

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Actually, one way of testing for convergence in floating point calculations is `a + b == a`. Then you know that `b` is small enough to be ignored. – Ted Hopp May 15 '11 at 3:17

Float numbers are represented in the form Significant digits × baseexponent(IEEE 754). In your case, float 1.82 = 1 + 0.5 + 0.25 + 0.0625 + ...

Since only a limited digits could be stored, therefore there will be a round error if the float number cannot be represented as a terminating expansion in the relevant base (base 2 in the case).

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You should always check relative differences with floating point numbers, not absolute values.

You need to read this, too.

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Computers don't store floating point numbers exactly. To accomplish what you are doing, you could store the original input as a string, and count the number of characters.

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you mean with ltoa()? I am not fond of this function as it is not very simple and requres me to work with non-constant char arrays.... What do you suggest to accomplish this? – Griffin May 15 '11 at 4:05
Sorry, I'm not a C/C++ person, so I don't know how specifically to do it – Sam Magura May 15 '11 at 4:46