*Short summary (TL;DR) is at the end of the answer.*

Untyped arbitrary-precision constants don't live at runtime, constants live only at compile time (during the compilation). That being said, Go does not have to represent constants with arbitrary precision at runtime, only when compiling your application.

Why? Because constants do not get compiled into the executable binaries. They don't have to be. Let's take your example:

```
const Huge = 1e1000
fmt.Println(Huge / 1e999)
```

There is a constant `Huge`

in the *source code* (and will be in the package object), but it won't appear in your executable. Instead a function call to `fmt.Println()`

will be recorded with a value passed to it, whose type will be `float64`

. So in the executable only a `float64`

value being `10.0`

will be recorded. There is no sign of any number being `1e1000`

in the executable.

This `float64`

type is derived from the *default* type of the *untyped* constant `Huge`

. `1e1000`

is a floating-point literal. To verify it:

```
const Huge = 1e1000
x := Huge / 1e999
fmt.Printf("%T", x) // Prints float64
```

Back to the arbitrary precision:

Spec: Constants:

Numeric constants represent exact values of arbitrary precision and do not overflow.

So constants represent exact values of arbitrary precision. As we saw, there is no need to represent constants with arbitrary precision at *runtime*, but the compiler still has to do something at *compile time*. And it *does*!

Obviously "infinite" precision cannot be dealt with. But there is no need, as the source code itself is not "infinite" (size of the source is finite). Still, it's not practical to *allow* truly arbitrary precision. So the spec gives some freedom to compilers regarding to this:

Implementation restriction: Although numeric constants have arbitrary precision in the language, a compiler may implement them using an internal representation with limited precision. That said, every implementation must:

- Represent integer constants with at least 256 bits.
- Represent floating-point constants, including the parts of a complex constant, with a mantissa of at least 256 bits and a signed exponent of at least 32 bits.
- Give an error if unable to represent an integer constant precisely.
- Give an error if unable to represent a floating-point or complex constant due to overflow.
- Round to the nearest representable constant if unable to represent a floating-point or complex constant due to limits on precision.
These requirements apply both to literal constants and to the result of evaluating constant expressions.

However, also note that when all the above said, the standard package provides you the means to still represent and work with values (constants) with "arbitrary" precision, see package `go/constant`

. You may look into its source to get an idea how it's implemented.

Implementation is in `go/constant/value.go`

. Types representing such values:

```
// A Value represents the value of a Go constant.
type Value interface {
// Kind returns the value kind.
Kind() Kind
// String returns a short, human-readable form of the value.
// For numeric values, the result may be an approximation;
// for String values the result may be a shortened string.
// Use ExactString for a string representing a value exactly.
String() string
// ExactString returns an exact, printable form of the value.
ExactString() string
// Prevent external implementations.
implementsValue()
}
type (
unknownVal struct{}
boolVal bool
stringVal string
int64Val int64 // Int values representable as an int64
intVal struct{ val *big.Int } // Int values not representable as an int64
ratVal struct{ val *big.Rat } // Float values representable as a fraction
floatVal struct{ val *big.Float } // Float values not representable as a fraction
complexVal struct{ re, im Value }
)
```

As you can see, the `math/big`

package is used to represent untyped arbitrary precision values. `big.Int`

is for example (from `math/big/int.go`

):

```
// An Int represents a signed multi-precision integer.
// The zero value for an Int represents the value 0.
type Int struct {
neg bool // sign
abs nat // absolute value of the integer
}
```

Where `nat`

is (from `math/big/nat.go`

):

```
// An unsigned integer x of the form
//
// x = x[n-1]*_B^(n-1) + x[n-2]*_B^(n-2) + ... + x[1]*_B + x[0]
//
// with 0 <= x[i] < _B and 0 <= i < n is stored in a slice of length n,
// with the digits x[i] as the slice elements.
//
// A number is normalized if the slice contains no leading 0 digits.
// During arithmetic operations, denormalized values may occur but are
// always normalized before returning the final result. The normalized
// representation of 0 is the empty or nil slice (length = 0).
//
type nat []Word
```

And finally `Word`

is (from `math/big/arith.go`

)

```
// A Word represents a single digit of a multi-precision unsigned integer.
type Word uintptr
```

**Summary**

At runtime: *predefined* types provide limited precision, but you can "mimic" arbitrary precision with certain packages, such as `math/big`

and `go/constant`

. At compile time: constants seemingly provide arbitrary precision, but in reality a compiler may not live up to this (doesn't have to); but still the spec provides minimal precision for constants that all compiler must support, e.g. integer constants must be represented with at least 256 bits which is 32 bytes (compared to `int64`

which is "only" 8 bytes).

When an executable binary is created, results of constant expressions (with arbitrary precision) have to be converted and represented with values of finite precision types – which may not be possible and thus may result in compile-time errors. Note that only *results* –not intermediate operands– have to be converted to finite precision, constant operations are carried out with arbitrary precision.

How this arbitrary or enhanced precision is implemented is not defined by the spec, `math/big`

for example stores "digits" of the number in a slice (where digits is not a digit of the base 10 representation, but "digit" is an `uintptr`

which is like base 4294967295 representation on 32-bit architectures, and even bigger on 64-bit architectures).