MoonBit is an end-to-end programming language toolchain for cloud and edge computing using WebAssembly. The IDE environment is available at https://try.moonbitlang.com without any installation; it does not rely on any server either.
Alpha, experimental. We expect MoonBit to reach beta status next year(2024).
- Generate significantly smaller WASM output than any existing solutions.
- Much faster runtime performance.
- State of the art compile-time performance.
- Simple but practical, data-oriented language design.
A MoonBit program consists of type definitions, function definitions, and variable bindings. The entry point of every package is a special init
function. The init
function is special in two aspects:
- There can be multiple
init
functions in the same package. - An
init
function can't be explicitly called or referred to by other functions. Instead, allinit
functions will be implicitly called when initializing a package. Therefore,init
functions should only consist of statements.
func init {
"Hello world!".print() // OK
}
func init {
let x = 1
x // fail
}
MoonBit distinguishes between statements and expressions. In a function body, only the last clause should be an expression, which serves as a return value. For example:
func foo() -> Int {
let x = 1
x + 1 // OK
}
func foo() -> Int {
let x = 1
x + 1 // fail
x + 2
}
Expressions include:
- Value literals (e.g. Boolean values, numbers, characters, strings, arrays, tuples, structs)
- Arithmetical, logical, or comparison operations
- Accesses to array elements (e.g.
a[0]
) or struct fields (e.gr.x
) or tuple components (e.g.t.0
) - Variables and (capitalized) enum constructors
- Anonymous local function definitions
match
andif
expressions
Statements include:
- Named local function definitions
- Local variable bindings
- Assignments
- While loops and related control constructs (
break
andcontinue
) return
statements- Any expression whose return type is
unit
Functions take arguments and produce a result. In MoonBit, functions are first-class, which means that functions can be arguments or return values of other functions.
Functions can be defined as top-level or local. We can use the func
keyword to define a top-level function that sums three integers and returns the result, as follows:
func add3(x: Int, y: Int, z: Int)-> Int {
x + y + z
}
Note that the arguments and return value of top-level functions require explicit type annotations. If the return type is omitted, the function will be treated as returning the unit type.
Local functions are defined using the fn
keyword. Local functions can be named or anonymous. Type annotations can be omitted for local function definitions: they can be automatically inferred in most cases. For example:
func foo() -> Int {
fn inc(x) { x + 1 } // named as `inc`
fn (x) { x + inc(2) } (6) // anonymous, instantly applied to integer literal 6
}
Functions, whether named or anonymous, are lexical closures: any identifiers without a local binding must refer to bindings from a surrounding lexical scope. For example:
let x = 3
func foo(x: Int) {
fn inc() { x + 1 } // OK, will return x + 1
fn fail() { y + 1 } // fail: The value identifier y is unbound.
}
A function can be applied to a list of arguments in parentheses:
add3(1, 2, 7)
This works whether add3
is a function defined with a name (as in the previous example), or a variable bound to a function value, as shown below:
var add3 = fn(x, y, z) { x + y + z }
add3(1, 2, 7)
The expression add3(1, 2, 7)
returns 10
. Any expression that evaluates to a function value is applicable:
let f = fn (x) { x + 1 }
let g = fn (x) { x + 2 }
(if true { f } else { g }) (3) // OK
A conditional expression consists of a condition, a consequent, and an optional else clause.
if x == y {
expr1
} else {
expr2
}
if x == y {
expr1
}
The else clause can also contain another if-else expression:
if x == y {
expr1
} else if z == k {
expr2
}
Curly brackets are used to group multiple expressions in the consequent or the else clause.
Note that a conditional expression always returns a value in MoonBit, and the return values of the consequent and the else clause must be of the same type.
The primary loop statement in MoonBit is the while
loop:
while x == y {
expr1
}
The while
statement doesn't yield anything; it only evaluates to ()
of unit type. MoonBit also provides the break
and continue
statements for controlling the flow of a loop.
Moonbit supports numeric literals, including decimal, binary, octal, and hexadecimal numbers.
To improve readability, you may place underscores in the middle of numeric literals such as 1_000_000
. Note that underscores can be placed anywhere within a number, not just every three digits.
- There is nothing surprising about decimal numbers.
let a = 1234
let b = 1_000_000 + a
- A binary number has a leading zero followed by a letter "B", i.e.
0b
/0B
. Note that the digits after0b
/0B
must be0
or1
.
let bin = 0b110010
let another_bin = 0B110010
- An octal number has a leading zero followed by a letter "O", i.e.
0o
/0O
. Note that the digits after0o
/0O
must be in the range from0
through7
:
let octal = 0o1234
let another_octal = 0O1234
- A hexadecimal number has a leading zero followed by a letter "X", i.e.
0x
/0X
. Note that the digits after the0x
/0X
must be in the range0123456789ABCDEF
.
let hex = 0XA
let another_hex = 0xA
String interpolation is a powerful feature in MoonBit that enables you to substitute variables within interpolated strings. This feature simplifies the process of constructing dynamic strings by directly embedding variable values into the text.
x := 42
"The answer is \(x)".print()
Variables used for string interpolation must support the to_string
method.
A tuple is a collection of finite values constructed using round brackets ()
with the elements separated by commas ,
. The order of elements matters; for example, (1,true)
and (true,1)
have different types. Here's an example:
func pack(a: Bool, b: Int, c: String, d: Float) -> (Bool, Int, String, Float) {
(a, b, c, d)
}
func init {
let quad = pack(false, 100, "text", 3.14)
let (bool_val, int_val, str, float_val) = quad
}
Tuples can be accessed via pattern matching or index:
func f(t : (Int, Int)) {
let (x1, y1) = t // access via pattern matching
// access via index
let x2 = t.0
let y2 = t.1
if (x1 == x2 && y1 == y2) {
"yes".print()
} else {
"no".print()
}
}
func init {
f((1, 2))
}
An array is a finite sequence of values constructed using square brackets []
, with elements separated by commas ,
. For example:
let array = [1, 2, 3, 4]
You can use array[x]
to refer to the xth element. The index starts from zero.
let array = [1, 2, 3, 4]
let a = array[2]
array[3] = 5
let b = a + array[3]
b.print() // prints 8
A variable can be declared as mutable or immutable using the keywords var
or let
, respectively. A mutable variable can be reassigned to a new value, while an immutable one cannot.
let zero = 0
func init {
var i = 10
i = 20
(i + zero).print()
}
There is a short-hand syntax sugar for local immutable bindings, e.g, using :=
.
func test () {
a := 3
b := "hello"
}
There are two ways to create new data types: struct
and enum
.
In MoonBit, structs are similar to tuples, but their fields are indexed by field names. A struct can be constructed using a struct literal, which is composed of a set of labeled values and delimited with curly brackets. The type of a struct literal can be automatically inferred if its fields exactly match the type definition. A field can be accessed using the dot syntax s.f
. If a field is marked as mutable using the keyword mut
, it can be assigned a new value.
struct User {
id: Int
name: String
mut email: String
}
func init {
let u = { id: 0, name: "John Doe", email: "john@doe.com" }
u.email = "john@doe.name"
u.email.print()
}
Note that you can also include methods associated with your record type, for example:
struct Stack {
mut elems: List[Int]
push: (Int) -> Unit
pop: () -> Int
}
Enum types are similar to algebraic data types in functional languages. An enum can have a set of cases. Additionally, every case can specify associated values of different types, similar to a tuple. The label for every case must be capitalized, which is called a data constructor. An enum can be constructed by calling a data constructor with arguments of specified types. The construction of an enum must be annotated with a type. An enum can be destructed by pattern matching, and the associated values can be bound to variables that are specified in each pattern.
enum List {
Nil
Cons (Int, List)
}
func print(l: List) {
match l {
Nil => "nil".print()
Cons(x, xs) => {
x.print();
",".print();
print(xs)
}
}
}
func init {
let l: List = Cons(1, Cons(2, Nil))
print(l)
}
We have shown a use case of pattern matching for enums, but pattern matching is not restricted to enums. For example, we can also match expressions against Boolean values, numbers, characters, strings, tuples, arrays, and struct literals. Since there is only one case for those types other than enums, we can pattern match them using let
/var
binding instead of match
expressions. Note that the scope of bound variables in match
is limited to the case where the variable is introduced, while let
/var
binding will introduce every variable to the current scope. Furthermore, we can use underscores _
as wildcards for the values we don’t care about.
let id = match u {
{ id: id, name: _, email: _ } => id
}
// is equivalent to
let { id: id, name: _, email: _ } = u
There are some other useful constructs in pattern matching. For example, we can use as
to give a name to some pattern, and we can use |
to match several cases at once. A variable name can only be bound once in a single pattern, and the same set of variables should be bound on both sides of |
patterns.
match expr {
e as Lit(n) => ...
Add(e1, e2) | Mul(e1, e2) => ...
_ => ...
}
Generics are supported in top-level function and data type definitions. Type parameters can be introduced within square brackets. We can rewrite the aforementioned data type List
to add a type parameter T
to obtain a generic version of lists. We can then define generic functions over lists like map
and reduce
.
enum List[T] {
Nil
Cons(T, List[T])
}
func map[S, T](self: List[S], f: (S) -> T) -> List[T] {
match self {
Nil => Nil
Cons(x, xs) => Cons(f(x), map(xs, f))
}
}
func reduce[S, T](self: List[S], op: (T, S) -> T, init: T) -> T {
match self {
Nil => init
Cons(x, xs) => reduce(xs, op, op(init, x))
}
}
MoonBit supports methods in a different way from traditional object-oriented languages. A method is defined as a top-level function with self
as the name of its first parameter. The self
parameter will be the subject of a method call. For example, l.map(f)
is equivalent to map(l, f)
. Such syntax enables method chaining rather than heavily nested function calls. For example, we can chain the previously defined map
and reduce
together with into_list
and print
to perform list operations using the method call syntax.
func into_list[T](self: array[T]) -> List[T] {
var res: List[T] = Nil
var i = self.length() - 1
while (i >= 0) {
res = Cons(self[i], res)
i = i - 1
}
res
}
func init {
[1, 2, 3, 4, 5].into_list().map(fn(x) { x * 2 }).reduce(fn(x, y) { x + y }, 0).print()
}
Another difference between a method and a regular function is that overloading is only supported by the method syntax. For example, we have multiple print functions, such as print_int
and print_float
, for different types, but using the method print
the type of the subject can be recognized and the appropriate overloaded version will be selected, such as 1.print()
and 1.0.print()
.
MoonBit supports operator overloading of builtin operators. The method name corresponding to a operator <op>
is op_<op>
. For example:
struct T {
x:Int
}
func op_add(self: T, other: T) -> T {
{ x: self.x + other.x }
}
func init {
let a = { x:0, }
let b = { x:2, }
(a + b).x.print()
}
Currently, the following operators can be overloaded:
operator name | method name |
---|---|
+ |
op_add |
- |
op_sub |
* |
op_mul |
/ |
op_div |
% |
op_mod |
- (unary) |
op_neg |
_[_] (get item) |
op_get |
_[_] = _ (set item) |
op_set |
By default, all function definitions and variable bindings are invisible to other packages; types without modifiers are abstract data types, whose name is exported but the internals are invisible. This design prevents unintended exposure of implementation details. You can use the pub
modifier before type
/func
/let
to make them fully visible, or put priv
before type
to make it fully invisible to other packages. You can also use pub
or priv
before field names to obtain finer-grained access control. However, it is important to note that:
- Struct fields cannot be defined as
pub
within an abstract or private struct since it makes no sense. - Enum constructors do not have individual visibility so you cannot use
pub
orpriv
before them.
struct R1 { // abstract data type by default
x: Int // implicitly private field
pub y: Int // ERROR: `pub` field found in an abstract type!
priv z: Int // WARNING: `priv` is redundant!
}
pub struct R2 { // explicitly public struct
x: Int // implicitly public field
pub y: Int // WARNING: `pub` is redundant!
priv z: Int // explicitly private field
}
priv struct R3 { // explicitly private struct
x: Int // implicitly private field
pub y: Int // ERROR: `pub` field found in a private type!
priv z: Int // WARNING: `priv` is redundant!
}
enum T1 { // abstract data type by default
A(Int) // implicitly private variant
pub B(Int) // ERROR: no individual visibility!
priv C(Int) // ERROR: no individual visibility!
}
pub enum T2 { // explicitly public enum
A(Int) // implicitly public variant
pub B(Int) // ERROR: no individual visibility!
priv C(Int) // ERROR: no individual visibility!
}
priv enum T3 { // explicitly private enum
A(Int) // implicitly private variant
pub B(Int) // ERROR: no individual visibility!
priv C(Int) // ERROR: no individual visibility!
}
Another useful feature supported in MoonBit is pub(readonly)
types, which are inspired by private types in OCaml. In short, values of pub(readonly)
types can be destructed by pattern matching and the dot syntax, but cannot be constructed or mutated in other packages. Note that there is no restriction within the same package where pub(readonly)
types are defined.
// Package A
pub(readonly) struct RO {
field: Int
}
func init {
let r = { field: 4 } // OK
let r = { ..r, field: 8 } // OK
}
// Package B
func print(r : RO) {
"{ field: ".print()
r.field.print() // OK
" }".print()
}
func init {
let r : RO = { field: 4 } // ERROR: Cannot create values of the public read-only type RO!
let r = { ..r, field: 8 } // ERROR: Cannot mutate a public read-only field!
}
Access control in MoonBit adheres to the principle that a pub
type, function, or variable cannot be defined in terms of a private type. This is because the private type may not be accessible everywhere that the pub
entity is used. MoonBit incorporates sanity checks to prevent the occurrence of use cases that violate this principle.
pub struct S {
x: T1 // OK
y: T2 // OK
z: T3 // ERROR: public field has private type `T3`!
}
// ERROR: public function has private parameter type `T3`!
pub func f1(_x: T3) -> T1 { T1::A(0) }
// ERROR: public function has private return type `T3`!
pub func f2(_x: T1) -> T3 { T3::A(0) }
// OK
pub func f3(_x: T1) -> T1 { T1::A(0) }
pub let a: T3 // ERROR: public variable has private type `T3`!
Moonbit features a structural interface system for overloading/ad-hoc polymorphism. Interface can be declared as follows:
interface I {
f(Self, ...) -> ...
}
There is no need to implement an interface explicitly. Types with the required methods automatically implements an interface. For example, the following interface:
interface Print {
print(Self)
}
is automatically implemented by builtin types such as Int
and String
.
When declaring a generic function/method, the type parameters can be annotated with the interface they should implement. For example:
interface Number {
op_add(Self, Self) -> Self
op_mul(Self, Self) -> Self
}
func square[N: Number](x: N) -> N {
x * x
}
Without the Number
requirement,
the expression x * x
in square
will result in a method/operator not found error.
Now, the function square
can be called with any type that implements Number
, for example:
func init {
square(2).print() // 4
square(1.5).print() // 2.25
square({ x: 2, y: 3 }).print() // (4, 9)
}
struct Point {
x: Int
y: Int
}
func op_add(self: Point, other: Point) -> Point {
{ x: self.x + other.x, y: self.y + other.y }
}
func op_mul(self: Point, other: Point) -> Point {
{ x: self.x * other.x, y: self.y * other.y }
}
func print(self: Point) {
let x = self.x
let y = self.y
"(\(x), \(y))".print()
}
Moonbit provides the following useful builtin interfaces:
interface Eq {
op_equal(Self, Self) -> Bool
}
interface Compare {
// `0` for equal, `-1` for smaller, `1` for greater
op_equal(Self, Self) -> Int
}
interface Hash {
hash(Self) -> Int
}
interface Show {
to_string(Self) -> String
}
interface Default {
Self::default() -> Self
}
Sometimes it is useful to have methods that do not have a self parameter.
For example, the builtin Default
interface describe types with a default value,
but constructing a default value should not depend on a self
value.
So Moonbit provides a special syntax for methods without a self
parameter:
func Int::default() -> Int {
0
}
func init {
Int::default().print()
}
Methods without self
must be called explicitly with their type name.
Methods without self
can be declaraed in interfaces and called with type parameters, for example:
interface I {
Self::one() -> Self
op_add(Self, Self) -> Self
}
func two[X: I]() -> X {
X::one() + X::one()
}
The introduction to the build system is available at MoonBit's Build System Tutorial.