Quick summary:

```
import "math/bits"
const (
MaxUint uint = (1 << bits.UintSize) - 1
MaxInt int = (1 << bits.UintSize) / 2 - 1
MinInt int = (1 << bits.UintSize) / -2
)
```

Background:

As I presume you know, the `uint`

type is the same size as either `uint32`

or `uint64`

, depending on the platform you're on. Usually, one would use the unsized version of these only when there is no risk of coming close to the maximum value, as the version without a size specification can use the "native" type, depending on platform, which tends to be faster.

Note that it tends to be "faster" because using a non-native type sometimes requires additional math and bounds-checking to be performed by the processor, in order to emulate the larger or smaller integer. With that in mind, be aware that the performance of the processor (or compiler's optimised code) is almost always going to be better than adding your own bounds-checking code, so if there is any risk of it coming into play, it may make sense to simply use the fixed-size version, and let the optimised emulation handle any fallout from that.

With that having been said, there are still some situations where it is useful to know what you're working with.

The package "math/bits" contains the size of `uint`

, in bits. To determine the maximum value, shift `1`

by that many bits, minus 1. ie: `(1 << bits.UintSize) - 1`

Note that when calculating the maximum value of `uint`

, you'll generally need to put it explicitly into a `uint`

(or larger) variable, otherwise the compiler may fail, as it will default to attempting to assign that calculation into a signed `int`

(where, as should be obvious, it would not fit), so:

```
const MaxUint uint = (1 << bits.UintSize) - 1
```

That's the direct answer to your question, but there are also a couple of related calculations you may be interested in.

According to the spec, `uint`

and `int`

are always the same size.

`uint`

either 32 or 64 bits

`int`

same size as `uint`

So we can also use this constant to determine the maximum value of `int`

, by taking that same answer and dividing by `2`

then subtracting `1`

. ie: `(1 << bits.UintSize) / 2 - 1`

And the minimum value of `int`

, by shifting `1`

by that many bits and dividing the result by `-2`

. ie: `(1 << bits.UintSize) / -2`

In summary:

**MaxUint:** `(1 << bits.UintSize) - 1`

**MaxInt:** `(1 << bits.UintSize) / 2 - 1`

**MinInt:** `(1 << bits.UintSize) / -2`

full example (should be the same as below)

```
package main
import "fmt"
import "math"
import "math/bits"
func main() {
var mi32 int64 = math.MinInt32
var mi64 int64 = math.MinInt64
var i32 uint64 = math.MaxInt32
var ui32 uint64 = math.MaxUint32
var i64 uint64 = math.MaxInt64
var ui64 uint64 = math.MaxUint64
var ui uint64 = (1 << bits.UintSize) - 1
var i uint64 = (1 << bits.UintSize) / 2 - 1
var mi int64 = (1 << bits.UintSize) / -2
fmt.Printf(" MinInt32: %d\n", mi32)
fmt.Printf(" MaxInt32: %d\n", i32)
fmt.Printf("MaxUint32: %d\n", ui32)
fmt.Printf(" MinInt64: %d\n", mi64)
fmt.Printf(" MaxInt64: %d\n", i64)
fmt.Printf("MaxUint64: %d\n", ui64)
fmt.Printf(" MaxUint: %d\n", ui)
fmt.Printf(" MinInt: %d\n", mi)
fmt.Printf(" MaxInt: %d\n", i)
}
```

`int(^uint(0) >> 1) // largest int`

extracted from golang.org/doc/effective_go.html#printing – Victor Jun 3 '17 at 16:05