Just to add to the other answers talking about IEEE-754 and x86: the issue is even more complicated than they make it seem. There is not "one" representation of 0.1 in IEEE-754 - there are two. Either rounding the last digit down or up would be valid. This difference **can and does actually occur**, because x86 does *not* use 64-bits for its internal floating-point computations; it actually uses 80-bits! This is called double extended-precision.

So, even among just x86 compilers, it sometimes happen that the same number is represented two different ways, because some computes its binary representation with 64-bits, while others use 80.

In fact, it can happen even with the same compiler, even on the same machine!

```
#include <iostream>
#include <cmath>
void foo(double x, double y)
{
if (std::cos(x) != std::cos(y)) {
std::cout << "Huh?!?\n"; //← you might end up here when x == y!!
}
}
int main()
{
foo(1.0, 1.0);
return 0;
}
```

See Why is `cos(x) != cos(y)`

even though `x == y`

? for more info.

What Every Computer Scientist Should Know About Floating-Point Arithmetic`0.111 < 0.111111`

, right? Now suppose you are computing 6/9.`0.667 > 0.666667`

, right? You can't have it that 6/9 in three digit decimal is`0.666`

because that is not the closest 3-digit decimal to 6/9!11more comments