# Swift 3 & 4 - making use of the `rounded(_:)`

method as blueprinted in the `FloatingPoint`

protocol

The `FloatingPoint`

protocol (to which e.g. `Double`

and `Float`

conforms) blueprints the `rounded(_:)`

method

```
func rounded(_ rule: FloatingPointRoundingRule) -> Self
```

Where `FloatingPointRoundingRule`

is an enum enumerating a number of different rounding rules:

`case awayFromZero`

Round to the closest allowed value whose magnitude is greater than or
equal to that of the source.

`case down`

Round to the closest allowed value that is less than or equal to the
source.

`case toNearestOrAwayFromZero`

Round to the closest allowed value; if two values are equally close,
the one with greater magnitude is chosen.

`case toNearestOrEven`

Round to the closest allowed value; if two values are equally close,
the even one is chosen.

`case towardZero`

Round to the closest allowed value whose magnitude is less than or
equal to that of the source.

`case up`

Round to the closest allowed value that is greater than or equal to
the source.

We make use of similar examples to the ones from @Suragch's excellent answer to show these different rounding options in practice.

`.awayFromZero`

Round to the closest allowed value whose magnitude is greater than or equal to that of the source; no direct equivalent among the C functions, as this uses, conditionally on sign of `self`

, `ceil`

or `floor`

, for positive and negative values of `self`

, respectively.

```
3.000.rounded(.awayFromZero) // 3.0
3.001.rounded(.awayFromZero) // 4.0
3.999.rounded(.awayFromZero) // 4.0
(-3.000).rounded(.awayFromZero) // -3.0
(-3.001).rounded(.awayFromZero) // -4.0
(-3.999).rounded(.awayFromZero) // -4.0
```

`.down`

Equivalent to the C `floor`

function.

```
3.000.rounded(.down) // 3.0
3.001.rounded(.down) // 3.0
3.999.rounded(.down) // 3.0
(-3.000).rounded(.down) // -3.0
(-3.001).rounded(.down) // -4.0
(-3.999).rounded(.down) // -4.0
```

`.toNearestOrAwayFromZero`

Equivalent to the C `round`

function.

```
3.000.rounded(.toNearestOrAwayFromZero) // 3.0
3.001.rounded(.toNearestOrAwayFromZero) // 3.0
3.499.rounded(.toNearestOrAwayFromZero) // 3.0
3.500.rounded(.toNearestOrAwayFromZero) // 4.0
3.999.rounded(.toNearestOrAwayFromZero) // 4.0
(-3.000).rounded(.toNearestOrAwayFromZero) // -3.0
(-3.001).rounded(.toNearestOrAwayFromZero) // -3.0
(-3.499).rounded(.toNearestOrAwayFromZero) // -3.0
(-3.500).rounded(.toNearestOrAwayFromZero) // -4.0
(-3.999).rounded(.toNearestOrAwayFromZero) // -4.0
```

This rounding rule can also be accessed using the zero argument `rounded()`

method.

```
3.000.rounded() // 3.0
// ...
(-3.000).rounded() // -3.0
// ...
```

`.toNearestOrEven`

Round to the closest allowed value; if two values are equally close, the even one is chosen; equivalent to the C `rint`

(/very similar to `nearbyint`

) function.

```
3.499.rounded(.toNearestOrEven) // 3.0
3.500.rounded(.toNearestOrEven) // 4.0 (up to even)
3.501.rounded(.toNearestOrEven) // 4.0
4.499.rounded(.toNearestOrEven) // 4.0
4.500.rounded(.toNearestOrEven) // 4.0 (down to even)
4.501.rounded(.toNearestOrEven) // 5.0 (up to nearest)
```

`.towardZero`

Equivalent to the C `trunc`

function.

```
3.000.rounded(.towardZero) // 3.0
3.001.rounded(.towardZero) // 3.0
3.999.rounded(.towardZero) // 3.0
(-3.000).rounded(.towardZero) // 3.0
(-3.001).rounded(.towardZero) // 3.0
(-3.999).rounded(.towardZero) // 3.0
```

If the purpose of the rounding is to prepare to work with an integer (e.g. using `Int`

by `FloatPoint`

initialization after rounding), we might simply make use of the fact that when initializing an `Int`

using a `Double`

(or `Float`

etc), the decimal part will be truncated away.

```
Int(3.000) // 3
Int(3.001) // 3
Int(3.999) // 3
Int(-3.000) // -3
Int(-3.001) // -3
Int(-3.999) // -3
```

`.up`

Equivalent to the C `ceil`

function.

```
3.000.rounded(.up) // 3.0
3.001.rounded(.up) // 4.0
3.999.rounded(.up) // 4.0
(-3.000).rounded(.up) // 3.0
(-3.001).rounded(.up) // 3.0
(-3.999).rounded(.up) // 3.0
```

### Addendum: visiting the source code for `FloatingPoint`

to verify the C functions equivalence to the different `FloatingPointRoundingRule`

rules

If we'd like, we can take a look at the source code for `FloatingPoint`

protocol to directly see the C function equivalents to the public `FloatingPointRoundingRule`

rules.

From swift/stdlib/public/core/FloatingPoint.swift.gyb we see that the default implementation of the `rounded(_:)`

method makes us of the mutating `round(_:)`

method:

```
public func rounded(_ rule: FloatingPointRoundingRule) -> Self {
var lhs = self
lhs.round(rule)
return lhs
}
```

From swift/stdlib/public/core/FloatingPointTypes.swift.gyb we find the default implementation of `round(_:)`

, in which the equivalence between the `FloatingPointRoundingRule`

rules and the C rounding functions is apparent:

```
public mutating func round(_ rule: FloatingPointRoundingRule) {
switch rule {
case .toNearestOrAwayFromZero:
_value = Builtin.int_round_FPIEEE${bits}(_value)
case .toNearestOrEven:
_value = Builtin.int_rint_FPIEEE${bits}(_value)
case .towardZero:
_value = Builtin.int_trunc_FPIEEE${bits}(_value)
case .awayFromZero:
if sign == .minus {
_value = Builtin.int_floor_FPIEEE${bits}(_value)
}
else {
_value = Builtin.int_ceil_FPIEEE${bits}(_value)
}
case .up:
_value = Builtin.int_ceil_FPIEEE${bits}(_value)
case .down:
_value = Builtin.int_floor_FPIEEE${bits}(_value)
}
}
```