ligo/gitlab-pages/docs/language-basics/functions.md

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---
id: functions
title: Functions
---
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LIGO features functions are the basic building block of contracts. For
example, entrypoints are functions.
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## Declaring Functions
<!--DOCUSAURUS_CODE_TABS-->
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There are two ways in PascaLIGO to define functions: with or without a
*block*.
### Blocks
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In PascaLIGO, *blocks* enable the sequential composition of
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instructions into an isolated scope. Each block needs to include at
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least one instruction.
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```pascaligo skip
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block { a := a + 1 }
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```
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If we need a placeholder, we use the instruction `skip` which leaves
the state unchanged. The rationale for `skip` instead of a truly
empty block is that it prevents you from writing an empty block by
mistake.
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```pascaligo skip
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block { skip }
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```
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Blocks are more versatile than simply containing instructions: they
can also include *declarations* of values, like so:
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```pascaligo skip
block { const a : int = 1 }
```
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Functions in PascaLIGO are defined using the `function` keyword
followed by their `name`, `parameters` and `return` type definitions.
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Here is how you define a basic function that computes the sum of two
integers:
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```pascaligo group=a
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function add (const a : int; const b : int) : int is
block {
const sum : int = a + b
} with sum
```
The function body consists of two parts:
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- `block { <instructions and declarations> }` is the logic of the function;
- `with <value>` is the value returned by the function.
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### Blockless functions
Functions that can contain all of their logic into a single
*expression* can be defined without the need of a block:
```pascaligo
function identity (const n : int) : int is block { skip } with n // Bad! Empty block not needed!
function identity (const n : int) : int is n // Blockless
```
The value of the expression is implicitly returned by the
function. Another example is as follows:
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```pascaligo group=b
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function add (const a: int; const b : int) : int is a + b
```
You can call the function `add` defined above using the LIGO compiler
like this:
```shell
ligo run-function gitlab-pages/docs/language-basics/src/functions/blockless.ligo add '(1,2)'
# Outputs: 3
```
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<!--CameLIGO-->
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Functions in CameLIGO are defined using the `let` keyword, like other
values. The difference is that a succession of parameters is provided
after the value name, followed by the return type. This follows OCaml
syntax. For example:
```cameligo group=c
let add (a : int) (b : int) : int = a + b
```
You can call the function `add` defined above using the LIGO compiler
like this:
```shell
ligo run-function gitlab-pages/docs/language-basics/src/functions/blockless.mligo add '(1,2)'
# Outputs: 3
```
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CameLIGO is a little different from other syntaxes when it comes to
function parameters. In OCaml, functions can only take one
parameter. To get functions with multiple arguments like we are used
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to in imperative programming languages, a technique called
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[currying](https://en.wikipedia.org/wiki/Currying) is used. Currying
essentially translates a function with multiple arguments into a
series of single argument functions, each returning a new function
accepting the next argument until every parameter is filled. This is
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useful because it means that CameLIGO supports
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[partial application](https://en.wikipedia.org/wiki/Partial_application).
Currying is however *not* the preferred way to pass function arguments
in CameLIGO. While this approach is faithful to the original OCaml,
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it is costlier in Michelson than naive function execution accepting
multiple arguments. Instead, for most functions with more than one
parameter, we should gather the arguments in a
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[tuple](language-basics/sets-lists-tuples.md) and pass the tuple in as
a single parameter.
Here is how you define a basic function that accepts two `ints` and
returns an `int` as well:
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```cameligo group=b
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let add (a, b : int * int) : int = a + b // Uncurried
let add_curry (a : int) (b : int) : int = add (a, b) // Curried
let increment (b : int) : int = add_curry 1 // Partial application
```
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You can run the `increment` function defined above using the LIGO
compiler like this:
```shell
ligo run-function gitlab-pages/docs/language-basics/src/functions/curry.mligo increment 5
# Outputs: 6
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```
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The function body is a single expression, whose value is returned.
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<!--ReasonLIGO--> Functions in ReasonLIGO are defined using the `let`
keyword, like other values. The difference is that a tuple of
parameters is provided after the value name, with its type, then
followed by the return type.
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Here is how you define a basic function that sums two integers:
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```reasonligo group=b
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let add = ((a, b): (int, int)) : int => a + b;
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```
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You can call the function `add` defined above using the LIGO compiler
like this:
```shell
ligo run-function gitlab-pages/docs/language-basics/src/functions/blockless.religo add '(1,2)'
# Outputs: 3
```
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The function body is a single expression, whose value is returned.
<!--END_DOCUSAURUS_CODE_TABS-->
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## Anonymous functions (a.k.a. lambdas)
It is possible to define functions without assigning them a name. They
are useful when you want to pass them as arguments, or assign them to
a key in a record or a map.
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Here is how to define an anonymous function:
<!--DOCUSAURUS_CODE_TABS-->
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<!--PascaLIGO-->
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```pascaligo group=c
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function increment (const b : int) : int is
(function (const a : int) : int is a + 1) (b)
const a : int = increment (1); // a = 2
```
You can check the value of `a` defined above using the LIGO compiler
like this:
```shell
ligo evaluate-value gitlab-pages/docs/language-basics/src/functions/anon.ligo a
# Outputs: 2
```
<!--CameLIGO-->
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```cameligo group=c
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let increment (b : int) : int = (fun (a : int) -> a + 1) b
let a : int = increment 1 // a = 2
```
You can check the value of `a` defined above using the LIGO compiler
like this:
```shell
ligo evaluate-value gitlab-pages/docs/language-basics/src/functions/anon.mligo a
# Outputs: 2
```
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<!--ReasonLIGO-->
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```reasonligo group=c
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let increment = (b : int) : int => ((a : int) : int => a + 1)(b);
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let a : int = increment (1); // a == 2
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```
You can check the value of `a` defined above using the LIGO compiler
like this:
```shell
ligo evaluate-value gitlab-pages/docs/language-basics/src/functions/anon.religo a
# Outputs: 2
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```
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<!--END_DOCUSAURUS_CODE_TABS-->
If the example above seems contrived, here is a more common design
pattern for lambdas: to be used as parameters to functions. Consider
the use case of having a list of integers and mapping the increment
function to all its elements.
<!--DOCUSAURUS_CODE_TABS-->
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<!--PascaLIGO-->
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```pascaligo group=c
function incr_map (const l : list (int)) : list (int) is
list_map (function (const i : int) : int is i + 1, l)
```
You can call the function `incr_map` defined above using the LIGO compiler
like so:
```shell
ligo run-function
gitlab-pages/docs/language-basics/src/functions/incr_map.ligo incr_map
"list [1;2;3]"
# Outputs: [ 2 ; 3 ; 4 ]
```
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<!--CameLIGO-->
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```cameligo group=c
let incr_map (l : int list) : int list =
List.map (fun (i : int) -> i + 1) l
```
You can call the function `incr_map` defined above using the LIGO compiler
like so:
```shell
ligo run-function
gitlab-pages/docs/language-basics/src/functions/incr_map.mligo incr_map
"list [1;2;3]"
# Outputs: [ 2 ; 3 ; 4 ]
```
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<!--ReasonLIGO-->
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```reasonligo group=c
let incr_map = (l : list (int)) : list (int) =>
List.map ((i : int) => i + 1, l);
```
You can call the function `incr_map` defined above using the LIGO compiler
like so:
```shell
ligo run-function
gitlab-pages/docs/language-basics/src/functions/incr_map.religo incr_map
"list [1;2;3]"
# Outputs: [ 2 ; 3 ; 4 ]
```
<!--END_DOCUSAURUS_CODE_TABS-->