--- id: unit-option-pattern-matching title: Unit, Option, Pattern matching --- Optionals are a pervasive programing pattern in OCaml. Since Michelson and LIGO are both inspired by OCaml, *optional types* are available in LIGO as well. Similarly, OCaml features a *unit* type, and LIGO features it as well. Both the option type and the unit types are instances of a more general kind of types: *variant types* (sometimes called *sum types*). ## The unit Type The `unit` type in Michelson or LIGO is a predefined type that contains only one value that carries no information. It is used when no relevant information is required or produced. Here is how it used. In PascaLIGO, the unique value of the `unit` type is `Unit`. ```pascaligo group=a const n : unit = Unit // Note the capital letter ``` In CameLIGO, the unique value of the `unit` type is `()`, following the OCaml convention. ```cameligo group=a let n : unit = () ``` In ReasonLIGO, the unique value of the `unit` type is `()`, following the OCaml convention. ```reasonligo group=a let n : unit = (); ``` ## Variant types A variant type is a user-defined or a built-in type (in case of options) that defines a type by cases, so a value of a variant type is either this, or that or... The simplest variant type is equivalent to the enumerated types found in Java, C++, JavaScript etc. Here is how we define a coin as being either head or tail (and nothing else): ```pascaligo group=b type coin is Head | Tail const head : coin = Head const tail : coin = Tail ``` ```cameligo group=b type coin = Head | Tail let head : coin = Head let tail : coin = Tail ``` ```reasonligo group=b type coin = Head | Tail; let head : coin = Head; let tail : coin = Tail; ``` The names `Head` and `Tail` in the definition of the type `coin` are called *data constructors*, or *variants*. In this particular, they carry no information beyond their names, so they are called *constant constructors*. In general, it is interesting for variants to carry some information, and thus go beyond enumerated types. In the following, we show how to define different kinds of users of a system. ```pascaligo group=c type id is nat type user is Admin of id | Manager of id | Guest const u : user = Admin (1000n) const g : user = Guest ``` ```cameligo group=c type id = nat type user = Admin of id | Manager of id | Guest let u : user = Admin 1000n let g : user = Guest ``` ```reasonligo group=c type id = nat; type user = | Admin (id) | Manager (id) | Guest; let u : user = Admin (1000n); let g : user = Guest; ``` In LIGO, a constant constructor is equivalent to the same constructor taking an argument of type `unit`, so, for example, `Guest` is the same value as `Guest (unit)`. ## Optional values The `option` type is a predefined variant type that is used to express whether there is a value of some type or none. This is especially useful when calling a *partial function*, that is, a function that is not defined for some inputs. In that case, the value of the `option` type would be `None`, otherwise `Some (v)`, where `v` is some meaningful value *of any type*. An example in arithmetic is the division operation: ```pascaligo group=d function div (const a : nat; const b : nat) : option (nat) is if b = 0n then (None: option (nat)) else Some (a/b) ``` ```cameligo group=d let div (a, b : nat * nat) : nat option = if b = 0n then (None: nat option) else Some (a/b) ``` ```reasonligo group=d let div = ((a, b) : (nat, nat)) : option (nat) => if (b == 0n) { (None: option (nat)); } else { Some (a/b); }; ``` ## Pattern matching *Pattern matching* is similiar to the `switch` construct in Javascript, and can be used to route the program's control flow based on the value of a variant. Consider for example the definition of a function `flip` that flips a coin. ```pascaligo group=e type coin is Head | Tail function flip (const c : coin) : coin is case c of Head -> Tail | Tail -> Head end ``` You can call the function `flip` by using the LIGO compiler like so: ```shell ligo run-function gitlab-pages/docs/language-basics/src/unit-option-pattern-matching/flip.ligo flip "Head" # Outputs: Tail(Unit) ``` ```cameligo group=e type coin = Head | Tail let flip (c : coin) : coin = match c with Head -> Tail | Tail -> Head ``` You can call the function `flip` by using the LIGO compiler like so: ```shell ligo run-function gitlab-pages/docs/language-basics/src/unit-option-pattern-matching/flip.mligo flip Head # Outputs: Tail(Unit) ``` ```reasonligo group=e type coin = | Head | Tail; let flip = (c : coin) : coin => switch (c) { | Head => Tail | Tail => Head }; ``` You can call the function `flip` by using the LIGO compiler like so: ```shell ligo run-function gitlab-pages/docs/language-basics/src/unit-option-pattern-matching/flip.religo flip Head # Outputs: Tail(Unit) ```