Go 1.10 has been released, and it adds a `math.Round()`

function. This function rounds to the nearest integer (which is basically a *"round to nearest 1.0"* operation), and using that we can very easily construct a function that rounds to the unit of our choice:

```
func Round(x, unit float64) float64 {
return math.Round(x/unit) * unit
}
```

Testing it:

```
fmt.Println(Round(0.363636, 0.05)) // 0.35
fmt.Println(Round(3.232, 0.05)) // 3.25
fmt.Println(Round(0.4888, 0.05)) // 0.5
fmt.Println(Round(-0.363636, 0.05)) // -0.35
fmt.Println(Round(-3.232, 0.05)) // -3.25
fmt.Println(Round(-0.4888, 0.05)) // -0.5
```

Try it on the Go Playground.

The original answer follows which was created before Go 1.10 when no `math.Round()`

existed, and which also details the logic behind our custom `Round()`

function. It's here for educational purposes.

In the pre-Go1.10 era there was no `math.Round()`

. But...

Rounding tasks can easily be implemented by a `float64`

=> `int64`

converison, but care must be taken as float to int conversion is *not rounding but keeping the integer part* (see details in Go: Converting float64 to int with multiplier).

For example:

```
var f float64
f = 12.3
fmt.Println(int64(f)) // 12
f = 12.6
fmt.Println(int64(f)) // 12
```

Result is `12`

in both cases, the integer part. To get the rounding "functionality", simply add `0.5`

:

```
f = 12.3
fmt.Println(int64(f + 0.5)) // 12
f = 12.6
fmt.Println(int64(f + 0.5)) // 13
```

So far so good. But we don't want to round to integers. If we'd wanted to round to 1 fraction digit, we would multiply by 10 before adding `0.5`

and converting:

```
f = 12.31
fmt.Println(float64(int64(f*10+0.5)) / 10) // 12.3
f = 12.66
fmt.Println(float64(int64(f*10+0.5)) / 10) // 12.7
```

So basically you multiply by the reciprocal of the unit you want to round to. To round to `0.05`

units, multiply by `1/0.05 = 20`

:

```
f = 12.31
fmt.Println(float64(int64(f*20+0.5)) / 20) // 12.3
f = 12.66
fmt.Println(float64(int64(f*20+0.5)) / 20) // 12.65
```

Wrapping this into a function:

```
func Round(x, unit float64) float64 {
return float64(int64(x/unit+0.5)) * unit
}
```

Using it:

```
fmt.Println(Round(0.363636, 0.05)) // 0.35
fmt.Println(Round(3.232, 0.05)) // 3.25
fmt.Println(Round(0.4888, 0.05)) // 0.5
```

Try the examples on the Go Playground.

Note that rounding `3.232`

with `unit=0.05`

will not print exactly `3.25`

but `0.35000000000000003`

. This is because `float64`

numbers are stored using finite precision, called the IEEE-754 standard. For details see Golang converting float64 to int error.

Also note that `unit`

may be "any" number. If it's `1`

, then `Round()`

basically rounds to nearest integer number. If it's `10`

, it rounds to tens, if it's `0.01`

, it rounds to 2 fraction digits.

Also note that when you call `Round()`

with a negative number, you might get surprising result:

```
fmt.Println(Round(-0.363636, 0.05)) // -0.3
fmt.Println(Round(-3.232, 0.05)) // -3.2
fmt.Println(Round(-0.4888, 0.05)) // -0.45
```

This is because –as said earlier– conversion is keeping the integer part, and for example integer part of `-1.6`

is `-1`

(which is greater than `-1.6`

; while integer part of `1.6`

is `1`

which is less than `1.6`

).

If you want `-0.363636`

to become `-0.35`

instead of `-0.30`

, then in case of negative numbers add `-0.5`

instead of `0.5`

inside the `Round()`

function. See our improved `Round2()`

function:

```
func Round2(x, unit float64) float64 {
if x > 0 {
return float64(int64(x/unit+0.5)) * unit
}
return float64(int64(x/unit-0.5)) * unit
}
```

And using it:

```
fmt.Println(Round2(-0.363636, 0.05)) // -0.35
fmt.Println(Round2(-3.232, 0.05)) // -3.25
fmt.Println(Round2(-0.4888, 0.05)) // -0.5
```

**EDIT:**

To address your comment: because you don't "like" the non-exact `0.35000000000000003`

, you proposed to format it and re-parse it like:

```
formatted, err := strconv.ParseFloat(fmt.Sprintf("%.2f", rounded), 64)
```

And this "seemingly" results in the exact result as printing it gives `0.35`

exactly.

But this is just an "illusion". Since `0.35`

cannot be represented with finite bits using IEEE-754 standard, doesn't matter what you do with the number, if you store it in a value of type `float64`

, it won't be exactly `0.35`

(but an IEEE-754 number being very close to it). What you see is `fmt.Println()`

printing it as `0.35`

because `fmt.Println()`

already does some rounding.

But if you attempt to print it with higher precision:

```
fmt.Printf("%.30f\n", Round(0.363636, 0.05))
fmt.Printf("%.30f\n", Round(3.232, 0.05))
fmt.Printf("%.30f\n", Round(0.4888, 0.05))
```

Output: it's not nicer (might be even uglier): try it on the Go Playground:

```
0.349999999999999977795539507497
3.250000000000000000000000000000
0.500000000000000000000000000000
```

Note that on the other hand `3.25`

and `0.5`

are exact because they can be represented with finite bits exactly, because representing in binary:

```
3.25 = 3 + 0.25 = 11.01binary
0.5 = 0.1binary
```

What's the lesson? It's not worth formatting and re-parsing the result, as it won't be exact either (just a different `float64`

value which –according to default `fmt.Println()`

formatting rules– might be nicer in printing). If you want nice printed format, just format with precision, like:

```
func main() {
fmt.Printf("%.3f\n", Round(0.363636, 0.05))
fmt.Printf("%.3f\n", Round(3.232, 0.05))
fmt.Printf("%.3f\n", Round(0.4888, 0.05))
}
func Round(x, unit float64) float64 {
return float64(int64(x/unit+0.5)) * unit
}
```

And it will be exact (try it on the Go Playground):

```
0.350
3.250
0.500
```

Or just multiply them by `100`

and work with integer numbers, so that no representation or rounding error may occur.

`0.05`

, for example, cannot be represented exactly. In 64-bit IEEE floating-point, it will probably be stored as`0.05000000000000000277555756156289135105907917022705078125`

. For most purposes, keep your floating-point values in full precision, and round them only when performing output or converting to a string. – Keith Thompson Dec 27 '17 at 20:24