Module Base__.Nothing

type t =

Having [@@deriving enumerate] may seem strange due to the fact that generated val all : t list is the empty list, so it seems like it could be of no use.

This may be true if you always expect your type to be Nothing.t, but [@@deriving enumerate] can be useful if you have a type which you expect to change over time. For example, you may have a program which has to interact with multiple servers which are possibly at different versions. It may be useful in this program to have a variant type which enumerates the ways in which the servers may differ. When all the servers are at the same version, you can change this type to Nothing.t and code which uses an enumeration of the type will continue to work correctly.

This is a similar issue to the identifiability of Nothing.t. As discussed below, another case where [@deriving enumerate] could be useful is when this type is part of some larger type.

val all : t list
val unreachable_code : t -> _

Because there are no values of type Nothing.t, a piece of code that has a value of type Nothing.t must be unreachable. In such an unreachable piece of code, one can use unreachable_code to give the code whatever type one needs. For example:

let f (r : (int, Nothing.t) Result.t) : int =
  match r with
  | Ok i -> i
  | Error n -> Nothing.unreachable_code n
;;

Note that the compiler knows that Nothing.t is uninhabited, hence this will type without warning:

let f (Ok i : (int, Nothing.t) Result.t) = i

It may seem weird that this is identifiable, but we're just trying to anticipate all the contexts in which people may need this. It would be a crying shame if you had some variant type involving Nothing.t that you wished to make identifiable, but were prevented for lack of Identifiable.S here.

Obviously, of_string and t_of_sexp will raise an exception.

include Base.Identifiable.S with type t := t
type t
val hash_fold_t : Base.Hash.state -> t -> Base.Hash.state
val hash : t -> Base.Hash.hash_value
include Base.Sexpable.S with type t := t
type t
val t_of_sexp : Sexplib0.Sexp.t -> t
val sexp_of_t : t -> Sexplib0.Sexp.t
include Base.Stringable.S with type t := t
type t
val of_string : string -> t
val to_string : t -> string
include Base.Comparable.S with type t := t
include Base__.Comparable_intf.Polymorphic_compare
include Base.Comparisons.Infix
type t
val (>=) : t -> t -> bool
val (<=) : t -> t -> bool
val (=) : t -> t -> bool
val (>) : t -> t -> bool
val (<) : t -> t -> bool
val (<>) : t -> t -> bool
val equal : t -> t -> bool
val compare : t -> t -> int

compare t1 t2 returns 0 if t1 is equal to t2, a negative integer if t1 is less than t2, and a positive integer if t1 is greater than t2.

val min : t -> t -> t
val max : t -> t -> t
val ascending : t -> t -> int

ascending is identical to compare. descending x y = ascending y x. These are intended to be mnemonic when used like List.sort ~compare:ascending and List.sort ~cmp:descending, since they cause the list to be sorted in ascending or descending order, respectively.

val descending : t -> t -> int
val between : t -> low:t -> high:t -> bool

between t ~low ~high means low <= t <= high

val clamp_exn : t -> min:t -> max:t -> t

clamp_exn t ~min ~max returns t', the closest value to t such that between t' ~low:min ~high:max is true.

Raises if not (min <= max).

val clamp : t -> min:t -> max:t -> t Base.Or_error.t
include Base.Comparator.S with type t := t
type t
type comparator_witness
val comparator : (tcomparator_witness) Base.Comparator.comparator
include Base__.Comparable_intf.Validate with type t := t
type t
val validate_lbound : min:t Base.Maybe_bound.t -> t Base.Validate.check
val validate_ubound : max:t Base.Maybe_bound.t -> t Base.Validate.check
val validate_bound : min:t Base.Maybe_bound.t -> max:t Base.Maybe_bound.t -> t Base.Validate.check
include Base.Pretty_printer.S with type t := t
type t
val pp : Base.Formatter.t -> t -> unit