**EDIT:** Moving the proposed solution at top of the relevant information.

You can use **set::precision** to see the proper precision.

Apart from the answer above, It is important to note that Whenever, You use float and decimal numbers **Rounding Errors** & **Precision** are an definite factor.

**What is an Precision Error?**

The precision of a floating point number is how many digits it can represent without losing any information it contains.

Consider the fraction `1/3`

. The decimal representation of this number is `0.33333333333333…`

with 3′s going out to infinity. An infinite length number would require infinite memory to be depicted with exact precision, but `float`

or `double`

data types typically only have `4`

or `8`

bytes. Thus Floating point & double numbers can only store a certain number of digits, and the rest are bound to get lost. Thus, there is no definite accurate way of representing float or double numbers with numbers that require more precision than the variables can hold.

**What is a Rounding Error?**

There is a non-obvious differences between `binary`

and `decimal (base 10)`

numbers.

Consider the fraction `1/10`

. In `decimal`

, this can be easily represented as `0.1`

, and `0.1`

can be thought of as an easily representable number. However, in binary, `0.1`

is represented by the infinite sequence: `0.00011001100110011…`

An example:

```
#include <iomanip>
int main()
{
using namespace std;
cout << setprecision(17);
double dValue = 0.1;
cout << dValue << endl;
}
```

This output is:

```
0.10000000000000001
```

And not

```
0.1.
```

This is because the double had to truncate the approximation due to it’s limited memory, which results in a number that is not exactly `0.1`

. Such an scenario is called a **Rounding error**.

So be aware of these errors when you use floar or double.