It's because 0.04 can't be exactly represented as a `float`

- and neither can the result of multiplying it by 100. The result is very slightly less than 4, so the cast to int truncates it.

Basically, if you want to use numbers represented accurately in decimal, you should use the `decimal`

type instead of `float`

or `double`

. See my articles on decimal floating point and binary floating point for more information.

EDIT: There's something more interesting going on here, actually... in particular, if you assign the result to a local variable first, that changes the result:

```
using System;
using System.Globalization;
class Test
{
static void Main()
{
// Assign first, then multiply and assign back, then print
float f = Foo();
f *= 100;
Console.WriteLine((int) f); // Prints 4
// Assign once, then multiply within the expression...
f = Foo();
Console.WriteLine((int) (f * 100)); // Prints 4
Console.WriteLine((int) (Foo() * 100)); // Prints 3
}
// No need to do parsing here. We just need to get the results from a method
static float Foo()
{
return 0.04f;
}
}
```

I'm not sure exactly what's going on here, but the exact value of 0.04f is:

```
0.039999999105930328369140625
```

... so it *does* make sense for it not to print 4, potentially.

I *can* force the result of 3 if the multiplication by 100 is performed with `double`

arithmetic instead of `float`

:

```
f = Foo();
Console.WriteLine((int) ((double)f * 100)); // Prints 3
```

... but it's not clear to me why that's happening in the original version, given that `float.Parse`

returns `float`

, not `double`

. At a guess, the result remains in registers and the subsequent multiplication is performed using `double`

arithmetic (which is valid according to the spec) but it's certainly a surprising difference.