Skip to content

a functional programming language with algebraic effects and handlers

License

Notifications You must be signed in to change notification settings

facet-lang/facet

Facet: a call-by-value functional language with algebraic effects, quantitative type theory, and staging

Caveat lector: facet is quite new, and this document is primarily aspirational. Many things do not work, are not implemented, or are poorly thought-out.

Features

  • 📈 functional programming!
  • ✋🏻 strict (call-by-value) evaluation order
  • 👷🏻‍♀️ algebraic effects

Goals

  • effects as sole mechanism for ad hoc polymorphism; arithmetic, comparison, etc., performed via effects (thus, can be overridden locally)
    • some system for (ideally coherent) defaulting
  • quantitative type theory controlling staging and erasure in particular
    • specialization & inlining of handlers
  • compilation
    • fine-grained incremental compilation
  • metaprogramming & general elaborator reflection via effects
  • syntax desugaring via effects
  • data representation as an effect; peano numerals & nat-as-int should be interconvertable
  • elaboration, optimization, & compilation reflected via an effectful DSL

Non-goals

  • elision of signature variables; I’m willing to be completely explicit (for now at least)

Development

Make sure you have a recent enough ghc (8.10+) and cabal (3+); I’m not testing against older versions. On macOS, I recommend ghcup.

I do just about everything via ghci, which can be conveniently initialized and launched as follows:

cabal build # make sure dependencies are known & installed
script/repl # actually launch the repl

haskell-language-server integration is also provided, and I edit in VS Code configured to use it.

Organization

Haskell sources for the compiler &c. are in src. Facet sources for its standard libraries are in lib.

Syntax

A quick overview of facet’s syntax. Note that this is subject to change.

Comments

Line comments start with #. There are no block comments.

# comments are like this

Declarations

Declarations live at the top level of a file, and have a name, a signature, and a body wrapped in braces.

unit1 : Unit
{ unit }

A declaration’s signature gives its type, and can also bind variables. Variables bound in the signature are in-scope in the body.

id1 : (x : Unit) -> Unit
{ x }

Functions

If we didn’t bind the variable in the signature, we could instead bind it by pattern matching in the body. Function bodies range over any variables unbound in the signature. For example, the above definition of id1 is equivalent to:

id2 : Unit -> Unit
{ x -> x }

Functions are typically defined in curried style: a function of two arguments is a function of one argument whose result is a function of one argument. Multiple variables can be bound either in the signature:

const1 : (a : Unit) -> (b : Unit) -> Unit
{ a }

the body:

const2 : Unit -> Unit -> Unit
{ a b -> a }

or a mixture:

const3 : (a : Unit) -> Unit -> Unit
{ b -> a }

Unused parameters can be ignored with a wildcard pattern, written as _, whether in the signature:

const4 : (a : Unit) -> (_ : Unit) -> Unit
{ a }

or the body:

const5 : Unit -> Unit -> Unit
{ a _ -> a }

From here on, we’ll prefer to bind variables in the signature rather than the body.

Types

Functions can have type parameters, which are bound in the signature like term variables, but written in initial caps and wrapped in curly braces instead of parentheses:

id3 : { A : Type } -> (a : A) -> A
{ a }

Type variables are in scope in the rest of the signature, and in the body. Unlike parameters, they cannot be bound in the body, only in the signature. There is no implicit generalization of free type variables in the signature (or elsewhere); free type are assumed to be globals, and will error if they’re not in scope.

Multiple type variables of the same kind can be bound separately:

const6 : { A : Type } -> { B : Type } -> (a : A) -> (b : B) -> A
{ a }

or can be combined into a single set of braces:

const7 : { A, B : Type } -> (a : A) -> (b : B) -> A
{ a }

Data

Data types are defined using a similar syntax to other declarations, but with init-caps names (like all Facet types). The block contains a comma-separated list of zero or more constructors, with init-lowercase names (like all Facet terms) followed by their types. For example, here is how you would define a boolean type (if one weren’t already defined for you):

Bool : Type
{ false : Bool
, true  : Bool }

Constructors with fields include them in their types:

BoolPair : Type
{ boolPair : Bool -> Bool -> BoolPair }

Patterns

Values can be examined and destructured by means of pattern matching. Function arguments—in curly braces, to the left of the arrow—are matched with patterns. The simplest case is a variable:

id : { A : Type } -> A -> A
{ x -> x }

If you don’t need to use the argument, you can also use a wildcard, written as an underscore (_), to ignore it:

const : { A, B : Type } -> A -> B -> A
{ a _ -> a }

Data constructors, introduced by datatypes, can be matched by mentioning their names (and further patterns for any fields) within parentheses; multiple pattern-matching clauses are separated by commas:

not : Bool -> Bool
{ (false) -> true
, (true)  -> false }

(Requiring parentheses around constructor patterns allows us to distinguish them from variable patterns, and thus to avoid accidentally introducing bugs when a constructor is renamed or typo’d.)

Patterns are matched in top-down order; the first matching clause will be executed. It is an error for no patterns to match.

TBD: exhaustiveness; tuples; effect constructors

Effects

Handlers

About

a functional programming language with algebraic effects and handlers

Topics

Resources

License

Code of conduct

Stars

Watchers

Forks

Releases

No releases published

Contributors 3

  •  
  •  
  •