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Ephel

Ephel is a language mixing functional programming and Ambient Calculus.

The functional paradigm is dedicated to the expression of behaviors, while the ambient paradigm is dedicated to structuring and topological management.

Functional programming layer

References:

The functional layer is strongly statically typed with dependent types.

It covers:

  • the core lambda calculus
  • dependent function types,
  • dependent product types,
  • dependent coproduct types,
  • dependent records (can subsume sigma type) and
  • dependent recursive types.

Cf. works on Nehtra for the type checker and Compiler for the execution.

A taste of Ephel functional programming layer

Module category.functor

First, we design the functor (quite classic) and, at the same time, we specify the laws to be verified by each incarnation. Otherwise, it's not a functor!

sig Map : (type -> type) -> type
val Map = F =>
    sig struct
        sig map : {A B:type} -> (A -> B) -> F A -> F B
        val _<$>_ : sig of map = map
    end

sig Functor : (type -> type) -> type
val Functor = F =>
    sig struct
        open Map F

        sig Laws :
            let open std.core in
            sig struct
                sig ''map id :=: id'' :
                    {A:type}
                 -> (a:F A)
                    -----------------
                 -> map id a :=: id a

                sig ''map f <| map g :=: map (f <| g)'' :
                    {A B C:type}
                 -> {f:B -> C}
                 -> {g:A -> B}
                 -> (a:F A)
                    -------------------------------------
                 -> (map f <| map g) a :=: map (f <| g) a
            end
    end

sig Api : type
val Api = Functor

In the type map id a :=: a the operator :=: refers to the propositional equality.

Module option

We can now propose an implementation of optional expression. For this purpose we propose the type definition thanks to the postfix operator _? to retrieve the expressivity offered by other languages like Swift, Dart or Kotlin for example.

-{ Type definition }-

sig _? : type -> type (infix 200)
val _? = A =>
    | None : A?
    | Some : A -> A?

-{ Constructors }-

val none : {A:type} -> A? = None
val some : {A:type} -> A -> A? = Some

Then we can propose a functor implementation dedicated to optional expressions. This implementation should provide a map but also an incarnation of the inner structure called Laws. Here proofs are trivial proceeding by structural induction and applying refl for reflexivity.

-{ Functor }-

val Functor : category.functor.Api _? =
    val struct
        val map = f =>
            | None => None
            | Some a => Some $ f a

        val Laws =
            val struct
                val ''map id :=: id'' =
                    | None   => refl
                    | Some _ => refl

                val ''map f <| map g :=: map (f <| g)'' =
                    | None   => refl
                    | Some _ => refl
            end
    end

Ambient programming layer

References:

Ephel provides three types dedicated to Ambient Calculus.

Ambient name

val name: ambient name =
    `test

Ambient capability

val in_action : ambient name -> ambient capability
    = name p => in name

val out_action : ambient name -> ambient capability
    = name p => out name

val open_action : ambient name -> ambient capability
    = name p => open name

val combine_action : ambient capability -> ambient capability -> ambient capability
    = a1 a2 => a1.a2 

Ambient process

val output : {A:type} -> A -> ambient process =
    = m => <m>
     
val input : (A:type) -> (A -> ambient process) -> ambient process =
    = A f => <x:A>.(f x)

val zero : ambient process =
    ()

val amb : ambient name -> ambient process -> ambient process 
    = n p => n[ p ] 

val parallel : ambient process -> ambient process -> ambient process
    = p1 p2 => p1 | p2 
    
val cap : ambient capability -> ambient process -> ambient process
    = c p => c.p     

-- Objective move
val go_cap : ambient capability -> ambient process -> ambient process
    = c p => go c.p       

A taste of Ephel Ambient Calculus layer

A basic ping pong game can be proposed using Ephel.

Topological approach

We identify three scoped ambient:

  • ping for the first player,
  • pong for the second player and
  • printer in charge of printing the winner
sig play : ambient name -> ambient name -> Nat -> ambient process
val play = sender receiver =>
    | Zero   => go (out sender.in `printer).<sender> 
    | Succ n => <x:Nat>.(play sender receiver x) | go (out sender.in receiver).<n> in

sig _to_ : (ambient name -> ambient process) -> ambient name -> ambient process
val _to_ = f p => f p

sig player : ambient name -> ambient name -> ambient process
val player = sender receiver =>
    sender[ <x:Nat>.(play sender receiver x) ]

 val main : ambient process =
    let open std.core in
    (player $ `ping to `pong)                   |
    (player $ `pong to `ping)                   |
    `printer[ (x:ambient name).(io.println x) ] |
    go in `ping.<42>

Functional approach

Since types are used for behavior selection this code can be revisited by removing all scoped Ambient for a simpler implementation using dependent types.

-{ Types and extractors }-

val ping : type =
    | Ping : nat -> ping

val ping_to_nat : ping -> nat =
    | Ping n => n

val pong : type =
    | Pong : nat -> pong

val pong_to_nat : pong -> nat =
    | Pong n => n

-{ Game defintion }-

sig play : {A:type} -> string -> (nat -> A) -> (A -> nat) -> A -> ambient process
val play = {A} who to_a from_a a =>
    let open std.core in
    let open dsl.-match- in
    from_a a match
    | Zero   => <who>
    | Succ n => <x:A>.(play who to_a from_a a) | <to_a n>

val main : ambient process =
    let open std.core in
    <n:pong>.(play "Bob"   Ping pong_to_nat n) | 
    <n:ping>.(play "Alice" Pong ping_to_nat n) |
    <x:string>.(io.println x)                                |
    <Pong 42>

Such an Ambient process implicitly captures the Actor paradigm.

Ambient and physical distribution [WIP]

References:

Since Ambient calculus targets concurrent systems with mobility we would like to distribute an ambient hierarchy physically.

For example, we can imagine the following ambient process

`A[ `B[ P ] | `C[ Q ] | `D[ R ] | <x:T>.F ]

with `A and `D ambients located in a physical process P1, `B in P2 and 'C in P3.

`A[ `B[ P ] | `C[ Q ] | `D[ R ] | <x:T>.F ]
 |   |    |     |    |                    |
 |   P2---+     P3---+                    |
 |                                        |
 P1---------------------------------------+

Ambient Scope and capability reduction

Each capability requires a specific scope:

  • in m: instructs the surrounding ambient to enter some sibling ambient m

  • out m: instructs the surrounding ambient to exit its parent ambient m

  • open m: instructs the surrounding ambient to dissolve the boundary of an ambient m

  • Note: `A@ in this formalism means ambient hosted in another physical process.

    P1: `A[ `B@ | `C@ | `D[ R ] | <x:T>.F ]
    P2: `A@[ `B[ P ] | `C@ | `D@ ]
    P3: `A@[ `B@ | `C[ Q ] | `D@ ]

For instance, in P2 `B (resp. P3 `C and P1 `D) has information related to:

  • its sibling ambient
  • its parent ambient

Reduction implementation sketch

Each scoped Ambient process is in charge of performing embedded capability and function application on the presence of events.

So, with this minimal representation, each Ambient can perform in, out and open with or without an objective move.

Functions are not represented in remote processes because the event used for its reduction is managed by the surrounding ambient.

Message movement using objective ambient capability

P1: `A[ `B@ | `C@ | `D[ R ] | <x:T>.F ]
P2: `A@[ `B[ go (out `B).<m> ] | `C@ | `D@ ]
P3: `A@[ `B@ | `C[ Q ] | `D@ ]

reduces to

P1: `A[ <m> | `B@ | `C@ | `D[ R ] | <x:T>.F ]
P2: `A@[ `B[] | `C@ | `D@ ]
P3: `A@[ `B@ | `C[ Q ] | `D@ ]

reduces to

P1: `A[ `B@ | `C@ | `D[ R ] | F{x:=m} ]
P2: `A@[ `B[] | `C@ | `D@ ]
P3: `A@[ `B@ | `C[ Q ] | `D@ ]

Message movement using ambient capability

P1: `A[ `B@ | `C@ | `D[ R ] | open `M.<x:T>.F ]
P2: `A@[ `B[ `M[ out `B.<m> ] ] | `C@ | `D@ ]
P3: `A@[ `B@ | `C[ Q ] | `D@ ]

reduces to

P1: `A[ `M[ <m> ] | `B@ | `C@ | `D[ R ] | open `M.<x:T>.F ]
P2: `A@[ `B[] | `C@ | `D@ ]
P3: `A@[ `B@ | `C[ Q ] | `D@ ]

reduces to

P1: `A[ <m> | `B@ | `C@ | `D[ R ] | <x:T>.F ]
P2: `A@[ `B[] | `C@ | `D@ ]
P3: `A@[ `B@ | `C[ Q ] | `D@ ]

reduces to

P1: `A[ `B@ | `C@ | `D[ R ] | F{x:=m} ]
P2: `A@[ `B[] | `C@ | `D@ ]
P3: `A@[ `B@ | `C[ Q ] | `D@ ]

About Ephel

Ephel

License

MIT License

Copyright (c) 2024 Didier Plaindoux

Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:

The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

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