Because `0.1`

isn't 0.1; that value isn't representable in double precision, so it gets rounded to the nearest double-precision number, which is exactly:

```
0.1000000000000000055511151231257827021181583404541015625
```

When you call `fmod`

, you get the remainder of division by the value listed above, which is exactly:

```
0.0999999999999999500399638918679556809365749359130859375
```

which rounds to `0.1`

(or maybe `0.09999999999999995`

) when you print it.

In other words, `fmod`

works perfectly, but you're not giving it the input that you think you are.

**Edit:** Your own implementation gives you the correct answer because it is *less accurate*, believe it or not. First off, note that `fmod`

computes the remainder without any rounding error; the only source of inaccuracy is the representation error introduced by using the value `0.1`

. Now, let's walk through your implementation, and see how the rounding error that it incurs exactly cancels out the representation error.

Evaluate `a - floor(a/n) * n`

one step at a time, keeping track of the exact values computed at each stage:

First we evaluate `1.0/n`

, where `n`

is the closest double-precision approximation to `0.1`

as shown above. The result of this division is approximately:

```
9.999999999999999444888487687421760603063276150363492645647081359...
```

Note that this value is not a representable double precision number -- so it gets *rounded*. To see how this rounding happens, let's look at the number in binary instead of decimal:

```
1001.1111111111111111111111111111111111111111111111111 10110000000...
```

The space indicates where the rounding to double precision occurs. Since the part after the round point is larger than the exact half-way point, this value rounds up to exactly `10`

.

`floor(10.0)`

is, predictably, `10.0`

. So all that's left is to compute `1.0 - 10.0*0.1`

.

In binary, the exact value of `10.0 * 0.1`

is:

```
1.0000000000000000000000000000000000000000000000000000 0100
```

again, this value is not representable as a double, and so is rounded at the position indicated by a space. This time it rounds down to exactly `1.0`

, and so the final computation is `1.0 - 1.0`

, which is of course `0.0`

.

Your implementation contains two rounding errors, which happen to exactly cancel out the representation error of the value `0.1`

in this case. `fmod`

, by contrast, is *always* exact (at least on platforms with a good numerics library), and exposes the representation error of `0.1`

.