What happens is

## 5 [expr]

10 The values of floating operands and of the results of floating expressions may be represented in greater precision and range than that required by the type; the types are not changed thereby.^{55)}

^{55)} The cast and assignment operators must still perform their specific conversions as described in 5.4, 5.2.9 and 5.17.

(C++03; practically identical 6.3.1.8(2) in C99 and the n1570 draft of C11; I'm confident that the gist is identical in C++11.)

In the following, I assume an IEEE-754 like binary floating point representation.

In a fractional hexadecimal notation,

```
1/10 = 1/2 * 3/15
= 1/2 * 0.33333333333...
= 2^(-4) * 1.999999999...
```

so when that is rounded to `b`

bits of precision, you get

```
2^(-4) * 1.99...9a // if b ≡ 0 (mod 4) or b ≡ 1 (mod 4)
2^(-4) * 1.99...98 // if b ≡ 2 (mod 4) or b ≡ 3 (mod 4)
```

where the last hex-digit in the fractional part is truncated after the 3,4,1,2 most significant bits respectively.

Now `320 = 2^6*(2^2 + 1)`

, so the result of `r * 320`

where `r`

is `0.1`

rounded to `b`

bits, is, in full precision (ignoring the power of 2),

```
6.66...68
+ 1.99...9a
-----------
8.00...02
```

with `b+3`

bits for `b ≡ 0 (mod 4)`

or `b ≡ 1 (mod 4)`

and

```
6.66...60
+ 1.99...98
-----------
7.ff...f8
```

with `b+2`

bits for `b ≡ 2 (mod 4)`

or `b ≡ 3 (mod 4)`

.

In each case, rounding the result to `b`

bits of precision yields exactly 32 and then you get `256/32 = 8`

as a final result. But if the intermediate result with greater precision is used, the calculated result of

```
256/(0.1 * 320)
```

is slightly smaller or larger than 8.

With the typical 32-bit `float`

with 24 (23+1) bits of precision, if the intermediate results are represented with a precision of at least 53 bits:

```
0.1f = 1.99999ap-4
0.1f * 320 = 32*(1 + 2^(-26))
256/(0.1f * 320) = 8/(1 + 2^(-26)) = 8 * (1 - 2^(-26) + 2^(-52) - ...)
```

In case 1, the result is directly converted¹ to `int`

from the intermediate result. Since the intermediate result is slightly smaller than 8, it gets truncated to 7.

In case 2, the intermediate result is stored in a `float`

before converting to `int`

, hence it is rounded to 24 bits of precision first, resulting in exactly 8.

Now if you leave off the `f`

suffix, `0.1`

is a `double`

(presumably with 53 bits of precision), the two `float`

s are promoted to `double`

for the calculation, and

```
0.1 = 1.999999999999ap-4
0.1 * 320 = 32*(1 + 2^(-55))
256/(0.1 * 320) = 8 * (1 - 2^(-55) + 2^(-110) - ...)
```

If the calculation is performed at `double`

precision `1 + 2^(-55) == 1`

and already `0.1 * 320 == 32`

.

If the calculation is performed at extended precision with 64 bits of precision (think x87) or more, it is likely that the literal `0.1`

isn't converted to `double`

precision at all and directly used with the extended precision, which again leads to the multiplication `0.1 * 320`

resulting in exactly 32.

If the literal `0.1`

is used at `double`

precision but the calculation is performed at higher precision, it would again yield 7 if the intermediate result is directly truncated to `int`

from the representation with greater precision and 8 if the excess precision is removed before the conversion to `int`

.

(Aside: gcc/g++ 4.5.1 yields 8 for all cases, regardless of optimisation level, on my 64-bit box, I haven't tried on a 32-bit box.)

¹ I'm not entirely sure, but I think that's a violation of the standard, it should first remove the excess precision. Any language lawyers?