Jane Street is a proprietary quantitative trading firm, focusing primarily on trading equities and equity derivatives. We use innovative technology, a scientific approach, and a deep understanding of markets to stay successful in our highly competitive field. We operate around the clock and around the globe, employing over 500 people in offices in New York, London and Hong Kong.

The markets in which we trade change rapidly, but our intellectual approach changes faster still. Every day, we have …

Jane Street is a proprietary quantitative trading firm, focusing primarily on trading equities and equity derivatives. We use innovative technology, a scientific approach, and a deep understanding of markets to stay successful in our highly competitive field. We operate around the clock and around the globe, employing over 500 people in offices in New York, London and Hong Kong.

The markets in which we trade change rapidly, but our intellectual approach changes faster still. Every day, we have new problems to solve and new theories to test. Our entrepreneurial culture is driven by our talented team of traders and programmers. At Jane Street, we don't come to work wanting to leave. We come to work excited to test new theories, have thought-provoking discussions, and maybe sneak in a game of ping-pong or two. Keeping our culture casual and our employees happy is of paramount importance to us.

As Jane Street grows, the quality of the development tools we use matters more and more. We increasingly work on the OCaml compiler itself: adding useful language features, fine-tuning the type system and improving the performance of the generated code. Alongside this, we also work on the surrounding toolchain, developing new tools for profiling, debugging, documentation and build automation.

We're looking to hire a developer with experience working on compilers to join us. That experience might be from working on a production compiler in industry or from working on research compilers in an academic setting. No previous experience with OCaml or functional programming languages is required.

We’re looking for candidates for both our London and New York offices. Benefits and compensation are highly competitive.

Software Developer

Jane Street is a proprietary quantitative trading firm, focusing primarily on trading equities and equity derivatives. We use innovative technology, a scientific approach, and a deep understanding of markets to stay successful in our highly competitive field. We operate around the clock and around the globe, employing over 500 people in offices in New York, London and Hong Kong.

The markets in which we trade change rapidly, but our intellectual approach changes faster still…

Software Developer

Jane Street is a proprietary quantitative trading firm, focusing primarily on trading equities and equity derivatives. We use innovative technology, a scientific approach, and a deep understanding of markets to stay successful in our highly competitive field. We operate around the clock and around the globe, employing over 500 people in offices in New York, London and Hong Kong.

The markets in which we trade change rapidly, but our intellectual approach changes faster still. Every day, we have new problems to solve and new theories to test. Our entrepreneurial culture is driven by our talented team of traders and programmers. At Jane Street, we don't come to work wanting to leave. We come to work excited to test new theories, have thought-provoking discussions, and maybe sneak in a game of ping-pong or two. Keeping our culture casual and our employees happy is of paramount importance to us.

We are looking to hire great software developers with an interest in functional programming. OCaml, a statically typed functional programming language with similarities to Haskell, Scheme, Erlang, F# and SML, is our language of choice. We've got the largest team of OCaml developers in any industrial setting, and probably the world's largest OCaml codebase. We use OCaml for running our entire business, supporting everything from research to systems administration to trading systems. If you're interested in seeing how functional programming plays out in the real world, there's no better place.

The atmosphere is informal and intellectual. There is a focus on education, and people learn about software and trading, both through formal classes and on the job. The work is challenging, and you get to see the practical impact of your efforts in quick and dramatic terms. Jane Street is also small enough that people have the freedom to get involved in many different areas of the business. Compensation is highly competitive, and there's a lot of room for growth.

You can learn more about Jane Street and our technology from our main site, janestreet.com. You can also look at a a talk given at CMU about why Jane Street uses functional programming (http://ocaml.janestreet.com/?q=node/61), and our programming blog (http://ocaml.janestreet.com).

We also have extensive benefits, including:

• 90% book reimbursement for work-related books
• 90% tuition reimbursement for continuing education
• Excellent, zero-premium medical and dental insurance
• Free lunch delivered daily from a selection of restaurants
• Catered breakfasts and fresh brewed Peet's coffee
• An on-site, private gym in New York with towel service
• Kitchens fully stocked with a variety of snack choices
• Full company 401(k) match up to 6% of salary, vests immediately

More information at http://janestreet.com/culture/benefits/

Bucket sort assumes input generated by a random process that distributes elements uniformly over the interval [0, 1).

The idea of bucket sort is to divide [0, 1) into n equal-sized subintervals or buckets, and then distribute the n input numbers into the buckets. To produce the output, sort the numbers in each bucket and then go through the buckets in order. Sorting a bucket can be done with insertion sort.

let rec insert x = function
  | [] -> [x]
  | h :: tl as ls ->
    if x <…

Bucket sort assumes input generated by a random process that distributes elements uniformly over the interval [0, 1).

The idea of bucket sort is to divide [0, 1) into n equal-sized subintervals or buckets, and then distribute the n input numbers into the buckets. To produce the output, sort the numbers in each bucket and then go through the buckets in order. Sorting a bucket can be done with insertion sort.

let rec insert x = function
  | [] -> [x]
  | h :: tl as ls ->
    if x < h then x :: ls else h :: insert x tl

let rec insertion_sort = function
  | [] | [_] as ls -> ls
  | h :: tl -> insert h (insertion_sort tl)

This code for bucket sort assumes the input is an n-element array a and that each element 0 ≤ a.(i) < 1. The code requires an auxillary array b.(0 .. n - 1) of lists (buckets).

let bucket_sort a =
  let n = Array.length a in
  let b = Array.make n [] in
  Array.iter
    (fun x ->
       let i =
         int_of_float (
           floor (float_of_int n *. x)
         ) in
        Array.set b i (x :: Array.get b i)
      ) a;
  Array.iteri
    (fun i l ->
       Array.set b i (insertion_sort l)
    ) b;
  Array.fold_left (fun acc bucket -> acc @ bucket) [] b
;;
bucket_sort [| 0.78; 0.17; 0.39; 0.26; 0.72; 0.94
             ; 0.21; 0.12; 0.23; 0.68|]

References:
[1] "Introduction to Algorithms" Section 9.4:Bucket Sort -- Cormen et. al. (Second ed.) 2001.

We are pleased to announce the release of a second release candidate for OPAM 2.0.0.

This new version brings us very close to a final 2.0.0 release, and in addition to many fixes, features big performance enhancements over the RC1.

Among the new features, we have squeezed in full sandboxing of package commands for both Linux and Mac OS, to protect our users from any misbehaving scripts.

NOTE: if upgrading manually from 2.0.0~rc, you need to run opam init --reinit -ni to enable sandboxing.

The ne…

We are pleased to announce the release of a second release candidate for OPAM 2.0.0.

This new version brings us very close to a final 2.0.0 release, and in addition to many fixes, features big performance enhancements over the RC1.

Among the new features, we have squeezed in full sandboxing of package commands for both Linux and Mac OS, to protect our users from any misbehaving scripts.

NOTE: if upgrading manually from 2.0.0~rc, you need to run opam init --reinit -ni to enable sandboxing.

The new release candidate also offers the possibility to setup a hook in your shell, so that you won’t need to run eval $(opam env) anymore. This is specially useful in combination with local switches, because with it enabled, you are guaranteed that running make from a project directory containing a local switch will use it.

The documentation has also been updated, and a preview of the opam 2 webpages can be browsed at http://opam.ocaml.org/2.0-preview/ (please report issues here). This provides the list of packages available for opam 2 (the 2.0 branch of opam-repository), including the compiler packages.

Installation instructions:

1. From binaries: run

   sh <(curl -sL https://raw.githubusercontent.com/ocaml/opam/master/shell/install.sh)

   or download manually from the Github “Releases” page to your PATH. In this case, don’t forget to run opam init --reinit -ni to enable sandboxing if you had version 2.0.0~rc manually installed.

2. From source, using opam:

   opam update; opam install opam-devel

   (then copy the opam binary to your PATH as explained, and don’t forget to run opam init --reinit -ni to enable sandboxing if you had version 2.0.0~rc manually installed)

3. From source, manually: see the instructions in the README.

Thanks a lot for testing out this new RC and reporting any issues you may find.

NOTE: this article is cross-posted on opam.ocaml.org and ocamlpro.com. Please head to the latter for comments!

In this blogpost we find out that it is possible to tweak the behavior of the Coq simpl tactic. We find it particularly useful when dealing with arithmetic goals on Z.

We just discovered an answer to a longstanding annoyance we faced when dealing with arithmetic Coq goals. Consider the following Coq goal, using integers on Z:

Require Import ZArith.
Open Scope Z_scope.

Goal forall a, 2 * a = 0 * a + a * 2.
  intros. simpl.

We call the simpl tactic to simplify 0 * a + ... into .... Unfort…

In this blogpost we find out that it is possible to tweak the behavior of the Coq simpl tactic. We find it particularly useful when dealing with arithmetic goals on Z.

We just discovered an answer to a longstanding annoyance we faced when dealing with arithmetic Coq goals. Consider the following Coq goal, using integers on Z:

Require Import ZArith.
Open Scope Z_scope.

Goal forall a, 2 * a = 0 * a + a * 2.
  intros. simpl.

We call the simpl tactic to simplify 0 * a + ... into .... Unfortunately, since * is defined by pattern matching on its first argument, simpl also unfolds 2 * a:

a : Z
============================
match a with
| 0 => 0
| Z.pos y' => Z.pos y'~0
| Z.neg y' => Z.neg y'~0
end = a * 2

This is both unconvenient and unsupported by automated tactics (such as omega or lia). One idea would be to make Z.mul opaque:

Opaque Z.mul.

This prevents both 2 * a and 0 * a from being simplified. This can be seen as a reasonable trade-off (omega will still be able to solve the goal).

However it also prevents reduction using eval compute, which breaks the PolTac library for example (interestingly, eval vm_compute ignores Opaque).

let x := (eval compute in (2*3)) in pose x.
(* x := 2*3 *)

let x := (eval vm_compute in (2*3)) in pose x.
(* x := 6 *)

A better solution can be found by reading the manual section for simpl (!). It is possible to customize for each definition the amount of unfolding performed by simpl. For example, the following instructs simpl to never unfold Z.mul:

Arguments Z.mul : simpl never.

Since this invocation only matters for simpl, eval compute and PolTac both continue to work.

let x := (eval compute in (2*3)) in pose x.
(* x := 6 *)

Goal forall a, 2 * a = 0 * a + a * 2.
  intros. simpl.
  (* 2 * a = 0 * a + a * 2 *)

And even better, we can achieve what we initially intended (which is to simplify away 0 * a), by instructing simpl to only unfold a definition if doing so does not introduce a match:

Arguments Z.mul : simpl nomatch.

Goal forall a, 2 * a = 0 * a + a * 2.
  intros. simpl.
  (* 2 * a = a * 2 *)

More configuration options are possible, and are thoroughly detailed in the manual page.

This article assumes familiarity with Dijkstra's shortest path algorithm. For a refresher, see [1]. The code assumes open Core is in effect and is online here.

The first part of the program organizes our thoughts about what we are setting out to compute. The signature summarizes the notion (for our purposes) of a graph definition in modular form. A module implementing this signature defines a type vertex_t for vertices, a type t for graphs and type extern_t

This article assumes familiarity with Dijkstra's shortest path algorithm. For a refresher, see [1]. The code assumes open Core is in effect and is online here.

The first part of the program organizes our thoughts about what we are setting out to compute. The signature summarizes the notion (for our purposes) of a graph definition in modular form. A module implementing this signature defines a type vertex_t for vertices, a type t for graphs and type extern_t : a representation of a t for interaction between an implemening module and its "outside world".

module type Graph_sig = sig
  type vertex_t [@@deriving sexp]
  type t [@@deriving sexp]
  type extern_t

  type load_error = [ `Duplicate_vertex of vertex_t ] [@@deriving sexp]
  exception Load_error of load_error [@@deriving sexp]

  val of_adjacency : extern_t -> [ `Ok of t | `Load_error of load_error ]
  val to_adjacency : t -> extern_t

  module Dijkstra : sig
    type state

    type error = [
      | `Relax of vertex_t
    ] [@@deriving sexp]
    exception Error of error [@@deriving sexp]

    val dijkstra : vertex_t -> t -> [ `Ok of state | `Error of error ]
    val d : state -> (vertex_t * float) list
    val shortest_paths : state -> (vertex_t * vertex_t list) list
  end

end

For reusability, the strategy for implementing graphs will be generic programming via functors over modules implementing s vertex type.

An implementation of the module type GRAPH defines a module type VERT which is required to provide a comparable type t. It further defines a module type S that is exactly module type Graph_sig above. Lastly, modules of type GRAPH provide a functor Make that maps any module of type VERT to new module of type S fixing extern_t to an adjacency list representation in terms of the native OCaml type 'a list and float to represent weights on edges.

module type GRAPH = sig
  module type VERT = sig
    type t[@@deriving sexp]
    include Comparable.S with type t := t
  end

  module type S = sig
    include Graph_sig
  end

  module Make : functor (V : VERT) ->
    S with type vertex_t = V.t
       and type extern_t = (V.t * (V.t * float) list) list
end

Implementation of module Graph is in outline this.

module Graph : GRAPH = struct
  module type VERT = sig
    type t[@@deriving sexp]
    include Comparable.S with type t := t
  end

  module type S = sig
    include Graph_sig
  end

  module Make : functor (V : VERT) ->
    S with type vertex_t = V.t
       and type extern_t = (V.t * (V.t * float) list) list
    =

    functor (V : VERT) -> struct
       ...
    end
end

Modules produced by applications of Make satisfy S. This requires suitable definitions of types vertext_t, t and extern_t. The modules Map and Set are available due to modules of type VERT being comparable in their type t.

      module Map = V.Map
      module Set = V.Set

      type vertex_t = V.t [@@deriving sexp]
      type t = (vertex_t * float) list Map.t [@@deriving sexp]
      type extern_t = (vertex_t * (vertex_t * float) list) list
      type load_error = [ `Duplicate_vertex of vertex_t ] [@@deriving sexp]
      exception Load_error of load_error [@@deriving sexp]

While the external representation extern_t of graphs is chosen to be an adjacency list representation in terms of association lists, the internal representation t is a vertex map of adjacency lists providing logarithmic loookup complexity. The conversion functions between the two representations "come for free" via module Map.

      let to_adjacency g = Map.to_alist g

      let of_adjacency_exn l =  match Map.of_alist l with
        | `Ok t -> t
        | `Duplicate_key c -> raise (Load_error (`Duplicate_vertex c))

      let of_adjacency l =
        try
          `Ok (of_adjacency_exn l)
        with
        | Load_error err -> `Load_error err

At this point the "scaffolding" for Dijkstra's algorithm, that part of GRAPH dealing with the representation of graphs is implemented.

The interpretation of Dijkstra's algorithm we adopt is functional : the idea is we loop over vertices relaxing their edges until all shortest paths are known. What we know on any recursive iteration of the loop is a current "state" (of the computation) and each iteration produces a new state. This next definition is the formal definition of type state.

      module Dijkstra = struct

        type state = {
          src    :                  vertex_t
        ; g      :                         t
        ; d      :               float Map.t
        ; pred   :            vertex_t Map.t
        ; s      :                     Set.t
        ; v_s    : (vertex_t * float) Heap.t
        }

• src : vertex_t, the source vertex;
• g : t, G the graph;
• d : float Map.t, d the shortest path weight estimates;
• pre : vertex_t Map.t, π the predecessor relation;
• s : Set.t, the set S of nodes for which the lower bound shortest path weight is known;
• v_s : (vertex_t * float) Heap.t, V - {S}, , the set of nodes of g for which the lower bound of the shortest path weight is not yet known ordered on their estimates.

Function invocation init src g compuates an initial state for the graph g containing the source node src. In the initial state, d is everywhere ∞ except for src which is 0. Set S (i.e. s) and the predecessor relation π (i.e. pred) are empty and the set V - {S} (i.e. v_s) contains all nodes.

        let init src g =
          let init x = match V.equal src x with
            | true -> 0.0 | false -> Float.infinity in
          let d = List.fold (Map.keys g) ~init:Map.empty
              ~f:(fun acc x -> Map.set acc ~key:x ~data:(init x)) in
          {
            src
          ; g
          ; s = Set.empty
          ; d
          ; pred = Map.empty
          ; v_s = Heap.of_list (Map.to_alist d)
                ~cmp:(fun (_, e1) (_, e2) -> Float.compare e1 e2)
          }

Relaxing an edge (u, v) with weight w (u, v) tests whether the shortest path to v so far can be improved by going through u and if so, updating d (v) and π (v) accordingly.

        type error = [
          | `Relax of vertex_t
        ] [@@deriving sexp]
        exception Error of error [@@deriving sexp]

        let relax state (u, v, w) =
          let {d; pred; v_s; _} = state in
          let dv = match Map.find d v with
            | Some dv -> dv
            | None -> raise (Error (`Relax v)) in
          let du = match Map.find d u with
            | Some du -> du
            | None -> raise (Error (`Relax u)) in
          if dv > du +. w then
            let dv = du +. w in
            (match Heap.find_elt v_s ~f:(fun (n, _) -> V.equal n v) with
            | Some tok -> ignore (Heap.update v_s tok (v, dv))
            | None -> raise (Error (`Relax v))
            );
            { state with
              d = Map.change d v
                  ~f:(function
                      | Some _ -> Some dv
                      | None -> raise (Error (`Relax v))
                    )
            ; pred = Map.set (Map.remove pred v) ~key:v ~data:u
            }
          else state

One iteration of the body of the loop of Dijkstra's algorithm consists of the node in V - {S} with the least shortest path weight estimate being moved to S and its edges relaxed.

        let dijkstra_exn src g =
          let rec loop ({s; v_s; _} as state) =
            match Heap.is_empty v_s with
            | true -> state
            | false ->
              let u = fst (Heap.pop_exn v_s) in
              loop (
                List.fold (Map.find_exn g u)
                  ~init:{ state with s = Set.add s u }
                  ~f:(fun state (v, w) -> relax state (u, v, w))
              )
          in loop (init src g)

        let dijkstra src g =
          try
            `Ok (dijkstra_exn src g)
          with
          | Error err -> `Error err

The shortest path estimates contained by a value of state is given by the projection d.

        let d state = Map.to_alist (state.d)

The shortest paths themselves are easily computed as,

   let path state n =
          let rec loop acc x =
            (match V.equal x state.src with
            | true -> x :: acc
            | false -> loop (x :: acc) (Map.find_exn state.pred x)
            ) in
          loop [] n

        let shortest_paths state =
          List.map (Map.keys state.g) ~f:(fun n -> (n, path state n))
      end
    end

The following program produces a concrete instance of the shortest path problem (with some evaluation output from the top-level).

module G : Graph.S with
  type vertex_t = char and type extern_t = (char * (char * float) list) list
  =
  Graph.Make (Char)

let g : G.t =
  match G.of_adjacency
          [ 's', ['u',  3.0; 'x', 5.0]
          ; 'u', ['x',  2.0; 'v', 6.0]
          ; 'x', ['v',  4.0; 'y', 6.0; 'u', 1.0]
          ; 'v', ['y',  2.0]
          ; 'y', ['v',  7.0]
          ]
  with
  | `Ok g -> g
  | `Load_error e -> failwiths "Graph load error : %s" e G.sexp_of_load_error
;;
let s = match (G.Dijkstra.dijkstra 's' g) with
  | `Ok s -> s
  | `Error e -> failwiths "Error : %s" e G.Dijkstra.sexp_of_error

;; G.Dijkstra.d s
- : (char * float) list =
[('s', 0.); ('u', 3.); ('v', 9.); ('x', 5.); ('y', 11.)]

;; G.Dijkstra.shortest_paths s
- : (char * char list) list =
[('s', ['s']); ('u', ['s'; 'u']); ('v', ['s'; 'u'; 'v']); ('x', ['s'; 'x']);
 ('y', ['s'; 'x'; 'y'])]

References:
[1] "Introduction to Algorithms" Section 24.3:Dijkstra's algorithm -- Cormen et. al. (Second ed.) 2001.

A new release of Alt-Ergo (version 2.2.0) is available.

You can get it from Alt-Ergo’s website. An OPAM package for it will be published in the next few days.

The major novelty of this release is a new experimental front-end that supports the SMT-LIB 2 language, extended prenex polymorphism. This extension is implemented as a standalone library, and is available here: https://github.com/Coquera/psmt2-frontend

The full list of CHANGES is available here. As usual, do not hesitate to report b…

A new release of Alt-Ergo (version 2.2.0) is available.

You can get it from Alt-Ergo’s website. An OPAM package for it will be published in the next few days.

The major novelty of this release is a new experimental front-end that supports the SMT-LIB 2 language, extended prenex polymorphism. This extension is implemented as a standalone library, and is available here: https://github.com/Coquera/psmt2-frontend

The full list of CHANGES is available here. As usual, do not hesitate to report bugs, to ask questions, or to give your feedback!

Original posted on linse's blog.

Image by Luc Viatour / https://Lucnix.be

In March 2018, I attended my first MirageOS hack retreat in Morrocco. MirageOS is a library operating system which allows everyone to build very small, specialized operating system kernels that are intended to run directly on the virtualization layer. The application code itself is the guest operating system kernel, and can be deployed at scale without the need for an extra containerization step in between. It is written …

Original posted on linse's blog.

Image by Luc Viatour / https://Lucnix.be

In March 2018, I attended my first MirageOS hack retreat in Morrocco. MirageOS is a library operating system which allows everyone to build very small, specialized operating system kernels that are intended to run directly on the virtualization layer. The application code itself is the guest operating system kernel, and can be deployed at scale without the need for an extra containerization step in between. It is written in OCaml and each kernel is built only with exactly the code that is necessary for the particular application. A pretty different approach from traditional operating systems. Linux feels huge all of a sudden.

I flew in from New York via Casablanca to Marrakesh, and then took a cab to the city center, to the main square, Jemaa El Fnaa. At Cafe de France, Hannes was picking me up and we walked back through the labyrinth of the Medina to the hostel Riad "Priscilla" where we lived with about 20 MirageOS folks, two turtles and a dog. We ate some food, and there were talks about Mirage's quickcheck-style fuzzing library Crowbar, and an API realized on top of a message queue written in OCaml.

Coming from compiler construction in Haskell and building "stateless" services for information retrieval in Scala, I have a good grasp of functional programming. The funny problem is I don't know much about OCaml yet.

At Etsy, I was part of the Core Platform team where we first used hhvm (Facebook's hip-hop virtual machine) on the API cluster, and then advocated to use their gradually typed "hack" language to introduce typing to the gigantic PHP codebase at Etsy. Dan Miller and I added types to the codebase with Facebook's hackificator, but then PHP 7 added the possibility of type annotations and great speedups, and PHP's own static analyzer phan was developed by Rasmus Lerdorf and Andrew Morrison to work with PHP's types. We abandoned the hackification approach. Why is this interesting? These were my first encounters with OCaml! The hack typechecker is written in OCaml, and Dan and I have read it to understand the gradual typing approach. Also, we played with pfff, a tool written in OCaml that allows structural edits on PHP programs, based on the abstact syntax tree. I made a list to translate between Haskell and OCaml syntax, and later Maggie Zhou and I used pfff to unify the syntax of several hundred endpoints in Etsy's internal API.

At the MirageOS retreat, I started my week reading "Real World OCaml", but got stuck because the examples did not work with the buildsystem used in the book. Stephen helped me to find a workaround, I made a PR to the book but it was closed since it is a temporary problem. Also, I started reading about OCaml's "lwt" library for concurrent programming. The abbreviation stands for lightweight threads and the library provides a monadic way to do multithreading, really similar to twitter futures in Scala. Asynchronous calls can be made in a thread, which then returns at some point when the call was successful or failed. We can do operations "inside" lwt with bind (>>=) in the same way we can flatMap over Futures in scala. The library also provides ways to run multiple threads in sequence or in parallel, and to block and wait. In the evening, there was a talk about a high-end smart card that based on a private start value can provide a succession of keys. The hardware is interesting, being the size of a credit card it has a small keypad and a screen. Some banks use these cards already (for their TAN system?), and we all got a sample card to play with.

One day I went swimming with Lix and Reynir, which was quite the adventure since the swimming pool was closed and we were not sure what to do. We still made it to the part that was still open, swam a lot and then got a cake for Hannes birthday which lead to a cake overflow since there were multiple cakes and an awesome party with candles, food and live music already. :D Thanks everyone for organizing!! Happy birthday Hannes!

I started reading another book, "OCaml from the very beginning", and working through it with Kugg. This book was more focused on algorithms and the language itself than on tooling and libraries, and the exercises were really fun to solve. Fire up OCaml's REPL utop and go! :D

At the same time I started reading the code for solo5 to get an understanding of the underlying hypervisor abstraction layer and the backends we compile to. This code is really a pleasure to read. It is called solo5 because of MirageOS's system calls, initially a set of 5 calls to the hypervisor, called hypercalls which sounds really futuristic. :D

So that's the other fun problem: I don't know too much about kernel programming yet. I did the Eudyptula (Linux kernel) challenge, an email-based challenge that sends you programming quests to learn about kernel programming. Over the course of the challenge, I've made my own Linux kernel module that says "Hello world!" but I have not built anything serious yet.

The next things I learned were configuring and compiling a MirageOS unikernel. Hannes showed me how this works. The config system is powerful and can be tailored to the unikernel we are about to build, via a config file. After configuring the build, we can build the kernel for a target backend of our choice. I started out with compiling to Unix, which means all network calls go through unix pipes and the unikernel runs as a simple unix binary in my host system, which is really useful for testing.

The next way to run MirageOS that I tried was running it in ukvm. For this setup you have to change the networking approach so that you can talk from the host system to you unikernel inside ukvm. In Linux you can use the Tun/Tap loopback interface for networking to wire up this connection.

We had a session with Jeremie about our vision for MirageOS which was super fun, and very interesting because people have all kinds of different backgrounds but the goals are still very aligned.

Another thing I learned was how to look at network traffic with wireshark. Sidney and I had previously recorded a TLS handshake with tcpdump and looked at the binary data in the pcap file with "hexfiend" next to Wikipedia to decode what we saw. Derpeter gave me a nice introduction about how to do this with wireshark, which knows about most protocols already and will do the decoding of the fields for us. We talked about all layers of the usual stack, other kinds of internet protocols, the iptables flow, and bgp / peeringDB. Quite interesting and I feel I have a pretty good foundational understanding about how the internet actually works now.

During the last days I wanted to write a unikernel that does something new, and I thought about monitoring, as there is no monitoring for MirageOS yet. I set up a grafana on my computer and sent some simple data packets to grafana from a unikernel, producing little peaks in a test graph. Reynir and I played with this a bit and restructured the program.

After this, the week was over, I walked back to Jemaa el Fnaa with Jeremie, I feel I learned a ton and yet am still at the very beginning, excited what to build next. On the way back I got stuck in a weird hotel in Casablanca due to the flight being cancelled, where I bumped into a Moroccan wedding and met some awesome travelling women from Brazil and the US who also got stuck. All in all a fun adventure!

History

On February 10th 2015 David Kaloper-Meršinjak and Hannes Mehnert launched (read also Amir's description) our bug bounty program in the form of our Bitcoin Piñata MirageOS unikernel. Thanks again to IPredator for both hosting our services and lending us the 10 Bitcoins! We analysed a bit more in depth after running it for five months. Mindy recently wrote about whacking the Bitcoin Piñata.

On March 18th 2018, after more than three years, IPredator, the lender of the Bitcoins,…

History

On February 10th 2015 David Kaloper-Meršinjak and Hannes Mehnert launched (read also Amir's description) our bug bounty program in the form of our Bitcoin Piñata MirageOS unikernel. Thanks again to IPredator for both hosting our services and lending us the 10 Bitcoins! We analysed a bit more in depth after running it for five months. Mindy recently wrote about whacking the Bitcoin Piñata.

On March 18th 2018, after more than three years, IPredator, the lender of the Bitcoins, repurposed the 10 Bitcoins for other projects. Initially, we thought that the Piñata would maybe run for a month or two, but IPredator, David, and I decided to keep it running. The update of the Piñata's bounty is a good opportunity to reflect on the project.

The 10 Bitcoin in the Piñata were fluctuating in price over time, at peak worth 165000€.

From the start of the Piñata project, we published the source code, the virtual machine image, and the versions of the used libraries in a git repository. Everybody could develop their exploits locally before launching them against our Piñata. The Piñata provides TLS endpoints, which require private keys and certificates. These are generated by the Piñata at startup, and the secret for the Bitcoin wallet is provided as a command line argument.

Initially the Piñata was deployed on a Linux/Xen machine, later it was migrated to a FreeBSD host using BHyve and VirtIO with solo5, and in December 2017 it was migrated to native BHyve (using ukvm-bin and solo5). We also changed the Piñata code to accomodate for updates, such as the MirageOS 3.0 release, and the discontinuation of floating point numbers for timestamps (asn1-combinators 0.2.0, x509 0.6.0, tls 0.9.0).

Motivation

We built the Piñata for many purposes: to attract security professionals to evaluate our from-scratch developed TLS stack, to gather empirical data for our Usenix Security 15 paper, and as an improvement to current bug bounty programs.

Most bug bounty programs require communication via forms and long wait times for human experts to evaluate the potential bug. This evaluation is subjective, intransparent, and often requires signing of non-disclosure agreements (NDA), even before the evaluation starts.

Our Piñata automates these parts, getting rid of wait times and NDAs. To get the private wallet key that holds the bounty, you need to successfully establish an authenticated TLS session or find a flaw elsewhere in the stack, which allows to read arbitrary memory. Everyone can track transactions of the blockchain and see if the wallet still contains the bounty.

Of course, the Piñata can't prove that our stack is secure, and it can't prove that the access to the wallet is actually inside. But trust us, it is!

Observations

I still remember vividly the first nights in February 2015, being so nervous that I woke up every two hours and checked the blockchain. Did the Piñata still have the Bitcoins? I was familiar with the code of the Piñata and was afraid there might be a bug which allows to bypass authentication or leak the private key. So far, this doesn't seem to be the case.

In April 2016 we stumbled upon an information disclosure in the virtual network device driver for Xen in MirageOS. Given enough bandwidth, this could have been used to access the private wallet key. We upgraded the Piñata and released the MirageOS Security Advisory 00.

We analysed the Piñata's access logs to the and bucketed them into website traffic and bounty connections. We are still wondering what happened in July 2015 and July 2017 where the graph shows spikes. Could it be a presentation mentioning the Piñata, or a new automated tool which tests for TLS vulnerabilities, or an increase in market price for Bitcoins?

The cumulative graph shows that more than 500,000 accesses to the Piñata website, and more than 150,000 attempts at connecting to the Piñata bounty.

You can short-circuit the client and server Piñata endpoint and observe the private wallet key being transferred on your computer, TLS encrypted with the secret exchanged by client and server, using socat -x TCP:ownme.ipredator.se:10000 TCP:ownme.ipredator.se:10002.

If you attempted to exploit the Piñata, please let us know what you tried! Via

hannesm@mastodon.social or a GitHub issue.

Since the start of 2018 we are developing robust software and systems at robur. If you like our work and want to support us with donations or development contracts, please get in touch with team@robur.io. Robur is a project of the German non-profit Center for the cultivation of technology. Donations to robur are tax-deductible in Europe.

@yomimono or @hannesm surely know if people have tried crowbar on the BTC Piñata. – @kensan@mastodon.social

tl;dr - yes, and it seems that ocaml-x509 is not trivially easy to trick.

Background

The Bitcoin Piñata

In 2015 David Kaloper-Mersinjak and Hannes Mehnert released ocaml-tls, an implementation of TLS (formerly known as SSL) written fully in OCaml. A full writeup of the stack is available in their Usenix Security 2015 paper, and as a series of blog posts on mirage.io. To acc…

@yomimono or @hannesm surely know if people have tried crowbar on the BTC Piñata. – @kensan@mastodon.social

tl;dr - yes, and it seems that ocaml-x509 is not trivially easy to trick.

Background

The Bitcoin Piñata

In 2015 David Kaloper-Mersinjak and Hannes Mehnert released ocaml-tls, an implementation of TLS (formerly known as SSL) written fully in OCaml. A full writeup of the stack is available in their Usenix Security 2015 paper, and as a series of blog posts on mirage.io. To accompany the release they also deployed a fully-automated bug bounty for the security stack – the bitcoin piñata.

The piñata will establish TLS connections only with endpoints presenting a certificate signed by its own, undisclosed certificate authority, but allows an attacker to easily listen to the encrypted traffic. The piñata always sends the same plaintext in such a connection: the private key to a wallet containing approximately 10 bitcoin. If the attacker can decrypt the ciphertext, or trick the piñata into negotiating a TLS connection with another host and disclosing the key, the information (and therefore the money) is theirs.

Crowbar

Crowbar is a library for writing tests. It combines a property-based API (like QuickCheck) with a coverage-driven generator of test cases (like the fuzzer American Fuzzy Lop). Crowbar tries to find counterexamples to stated properties by prioritizing the generation of test cases which touch more code. It is very good at finding counterexamples.

Testing ocaml-x509

TLS connections are usually authenticated via X509 certificates. ocaml-tls uses ocaml-x509 for this purpose, which is written as a standalone library. There is a clear separation of concerns between ocaml-x509 and ocaml-tls, and a straightforward API for certificate operations in ocaml-x509; both features help tremendously in writing tests for certificate handling.

Stating Tests

Of the possible operations in X509, the most interesting in the context of the BTC piñata are those related to certificate validation. We expect the piñata to check whether a certificate provided by the attacker has a trust chain to any CA it is aware of. This suggests a property we might want to find a counterexample to: * certificates signed by CA m will not be judged valid unless CA m is provided as a trust anchor.

If we can find a counterexample, we’re well on the way to getting the piñata to negotiate a TLS connection with an endpoint presenting a certificate not signed by the CA it generated at boot time.

Generating Certificates

In order to test this property, we need to be able to call X509.Validation.verify_chain_of_trust with something of type X509.CA.t (representing the certificate authority; for the piñata, this is a known and trusted value) and something of type X509.t (representing the certificate; for the piñata, this is presented by the remote host of the TLS connection).

For our tests, we’ll allow Crowbar’s random generators to specify most parts of the certificate, with the important exception of the key material – generating this randomly will cause the execution of each test to be very slow, and it’s not the goal of this testing to try to brute-force the key of our test CA.

The generators for certificates are largely automatically created by ppx_deriving_crowbar, although some manual help is needed to include generators for data types in dependencies used by X509 (and generators for their dependencies and dependencies’ dependencies). A maximalist interpretation can be seen in this iteration of the tests, which uses ppx_deriving to automatically generate equality tests and pretty-printers as well as generators for many of the relevant types.

Increasing Stability

Since we want all randomness in the test execution to be driven by the fuzzer, it’s important to remove other sources of entropy in the code execution. Luckily, ocaml-x509 and the cryptography library underneath it, nocrypto, were written considerately, and there is a facility for providing a constant seed to the pseudorandom number generator. Using the same seed across all test runs removes noise from the measurement of coverage between different test runs.

Running Tests

Tests built with the Crowbar library need to be run via afl-fuzz. To automatically launch afl-fuzz in a manner that uses all available computing resources and reports failures as quickly as possible, we used ocaml-bun. You can see the results of such a test run in Travis CI here.

The number of executions per second is appallingly low for OCaml native code running in afl-fuzz (cryptography is hard!); to compensate I ran this code over a weekend locally instead of briefly on whatever free resources Travis would give me.

Results

Many certificates with silly sets of extensions were generated:

`Priv_key_period (`Not_after (0066-02-08 09:28:58 +00:00))
`Subject_alt_name ([`EDI_party (((Some "mmmmmmmmmxmmmmmmmmmmmmmrs\146n\020sh&&&&&&&&&&.&&&'&&t\014the&w[rn Bx WrV"),
                                 "c\130 s'\186\186\186\186\186\186\186Te@rica tbiitx WrVc\127 s', or soTe@wos\127\141\018o\139\255repeeseb u"));
                                                      `Other ((0.32, "t \228ay of\015t"))])
                                                      `Priv_key_period (`Not_after (1088-06-01 06:08:11 +00:00))

`CRL_distribution_points ([((Some `Relative ([`Generation ("EEElE$EE \127\255E'EEElEEEYE$EE\151ai4RgEbEE\151a\214\214\214\235\214\214\214\214bnt\225")
                                               ])),
                            None,
                            (Some [`Surname ("~~~~~~~~~~EEEYE$EEB\127\255E'EEElEEEYE$EE\151a\214\214\214\235\214\214\214\214\214\214\214\214\214\214\214\214\198\214\214\214\215\214\214\214\214 \214")
                                    ]))
                            ])

`Certificate_issuer ([])
`Policies ([`Something (0.36.3703494230495416691)])`Certificate_issuer (
[])
`Subject_alt_name ([`Other ((2.2839008736452811263, "\140abbi\131\129\b',"));
                     `URI ("'[cay@")])

As we hoped, a certificate signed by the wrong CA with these sets of extensions don’t validate. ocaml-x509 isn’t tricked by arbitrarily ridiculous sets of extensions in a signed certificate, and I didn’t manage to steal any bitcoin.

Future and Related Work

None of this work targets ocaml-tls or any of the more general parts of the stack run by the piñata. Notably, neither tcpip which provides the TCP, IPv4, and Ethernet implementations, nor any of the hypervisor-specific virtual network devices, are examined by this work. (This includes mirage-net-xen, the originator of the only MirageOS security advisory to date.) With releases of all tooling used to test ocaml-x509 available via opam, this is easier to rectify than it previously was!

Acknowledgements

Thanks to OCaml Labs for funding this work, IPredator for stuffing the piñata, and robur.io for future and continuing work in building resilient systems.

As we are preparing to work on the Tezos Protocol, we’re still actively keeping the pace on the block explorer TZScan.io, adding cool information for baking accounts. We’d like to allow people to see who is contributing to the network and to understand the distribution of rolls, rights, etc.

For starters, we are showing the roll balance used for baking in the current cycle and the rolls history of a baker.

http://tzscan.io/tz1MqVR7hnZwH1FoQ7swjamanNxrXtNVAQ7v?default=baking

Enjoy, mo…

As we are preparing to work on the Tezos Protocol, we’re still actively keeping the pace on the block explorer TZScan.io, adding cool information for baking accounts. We’d like to allow people to see who is contributing to the network and to understand the distribution of rolls, rights, etc.

For starters, we are showing the roll balance used for baking in the current cycle and the rolls history of a baker.

http://tzscan.io/tz1MqVR7hnZwH1FoQ7swjamanNxrXtNVAQ7v?default=baking

Enjoy, more to come in the next weeks!

In some occasions, using the Coq proof assistant stops resembling a normal software development activity, and becomes more similar to puzzle solving.

Similarly to the excellent video games of the Zachtronics studio (TIS-100, SpaceChem, …), the system provides you with puzzles where obstacles have to be side-stepped using a fair amount of tricks and ingenuity, and finally solving the problem has often no other utility than the satisfaction of having completed it.

In this blog-post, I would li…

In some occasions, using the Coq proof assistant stops resembling a normal software development activity, and becomes more similar to puzzle solving.

Similarly to the excellent video games of the Zachtronics studio (TIS-100, SpaceChem, …), the system provides you with puzzles where obstacles have to be side-stepped using a fair amount of tricks and ingenuity, and finally solving the problem has often no other utility than the satisfaction of having completed it.

In this blog-post, I would like to present what I think is one such situation. What the puzzle is, how we solved it, and why you shouldn’t probably do that if you like spending your time in a useful manner.

Prelude

A few months ago, I was wondering if it was possible to count the number of exists in front of the goal, using Ltac (the tactic language of Coq). That is, write a tactic that would for example produce 3 on the following goal:

====================================
  exists x y z : nat, x + y = z

“That’s easy”, I thought. “I will just write a recursive function in Ltac”. First, we check that we can get the body of the exists by matching on the goal – this seems to work as expected:

Goal exists x y z : nat, x + y = z.
  match goal with |- exists x, ?G' => idtac G' end.
  (* Prints (exists y z : nat, x + y = z) *)

Then, we write a tactic to do this recursively, walking down the type of the goal until there is no exists in front of it.

Ltac count_exists_naive_aux G n :=
  lazymatch G with
  | exists x, ?G' => count_exists_naive_aux G' (S n)
  | _ => constr:(n)
  end.

Ltac count_exists_naive :=
  match goal with |- ?G =>
    let x := count_exists_naive_aux G 0 in
    pose x
  end.

But this does not work, and fails with the error below. It seems Ltac does not handle terms with free variables.

Error: Must evaluate to a closed term
offending expression:
G
this is an object of type constr_under_binders

At this point, the reasonable choice would be to give up, write specialized versions of the tactic for 0 to 7 exists (who has goals with more than 7 exists anyway?), and wait for one of the successors of Ltac (Ltac2 maybe?) to come up without these limitations. Unreasonably, I sought the help of Cyprien Mangin, my local puzzle game and Coq expert, and we came up with the following solution.

A first idea: “destruct”ing the goal

A first idea: one thing that we can do iteratively on a exists x y z ... term is splitting it using destruct – if we have it as an hypothesis. For example:

(* Goal:
   H : exists x y z : nat, x + y = z
   ====================================
     True
*)

  Ltac count_in_hyp H acc kont :=
    lazymatch type of H with
    | exists _, _ => destruct H as [? H]; count_in_hyp H (S acc) kont
    | _ => kont acc
    end.

  count_in_hyp H 0 ltac:(fun n => pose n).

(* Goal:
   x, x0, x1 : nat
   H : x + x0 = x1
   n := 3 : nat
   ====================================
     True
*)

Notice we had to do the “standard trick” of writing the tactic in continuation passing style (using kont here as a continuation to return the number of exists). This is required since a Ltac tactic cannot do side-effects on the goal (here, destruct) and at the same time return a term.

Now, we want to count the number of exists in the goal, not in an hypothesis. How could we turn the goal into an hypothesis – after all, these exists are something we need to provide, not something we get. In fact, it is possible to get a sub-goal with an hypothesis of the same type as the goal – simply, this sub-goal won’t be much relevant for proving the goal. We define the following helper lemma:

Definition helper_lemma : forall P Q, (P -> True) -> Q -> Q :=
  fun P Q _ Q_proof => Q_proof.

Applying this lemma produces an extra sub-goal with an hypothesis of type P. Notice how the proof term corresponding to this sub-goal is completely discarded in the definition of helper_lemma: this sub-goal is only relevant for our Ltac tricks. To get a sub-goal which allows destructing the exists in front of the goal, we do:

(* Goal:
   ====================================
     exists x y z : nat, x + y = z
*)

  match goal with |- ?G => apply (helper_lemma G) end;
  [ intro H | ].

(* Goal 1:
   H : exists x y z : nat, x + y = z
   ====================================
     True

   Goal 2:
   ====================================
     exists x y z : nat, x + y = z
*)

  count_in_hyp H 0 ltac:(fun n => pose n).

(* Goal 1:
   x, x0, x1 : nat
   H : x + x0 = x1
   n := 3 : nat
   ====================================
     True

   Goal 2:
   ====================================
     exists x y z : nat, x + y = z
*)

Second idea: communicating through evars

We are not done yet: we can count the number of exists in the first – dummy – sub-goal, but we need to transmit this information to the main sub-goal.

The second idea is to propagate this information using an “evar”. An evar is a Coq term representing a “hole”: its definition is not known yet, and will be given later in the proof. This discipline only exists when constructing the proof: evars do not appear in the proof term, where everything happens in order.

The idea here is to introduce an evar before applying our auxiliary helper_lemma. This evar will appear in the context of both sub-goals introduced by the lemma: in the first one, we can “instantiate” it (ie. set its definition) with the number of exists computed, and use it in the second sub-goal.

This gives us:

  evar (n : nat).

(* Goal:
   n := ?n : nat
   ====================================
     exists x y z : nat, x + y = z
*)

  match goal with |- ?G => apply (helper_lemma G) end;
  [ intro H;
    let x := count_in_hyp H 0 in
    instantiate (n := x);
    exact I
  | ].

(* Goal:
   n := 3 : nat
   ====================================
     exists x y z : nat, x + y = z
*)

Hurray! It works. We can wrap this in a reusable tactic:

Ltac count_in_ty G kont :=
  let n := fresh "n" in
  evar (n : nat);
  apply (helper_lemma G); [
    let H := fresh in
    intro H; count_in_hyp H 0 ltac:(fun x => instantiate (n := x));
    exact I
  | kont n ].

Third idea: cleaning up

The tactic above indeed works, and successfully counts the number of exists in the goal. However, it is still a bit messy. In particular, the trick of using a helper lemma shows up in the proof term. Using Show Proof after running count_in_ty on the goal yields:

(let n := 3 in
 helper_lemma (exists x y z : nat, x + y = z) (exists x y z : nat, x + y = z)
   (fun H : exists x y z : nat, x + y = z =>
    match H with
    | ex_intro _ x (ex_intro _ x0 (ex_intro _ _ _)) => I
    end) ?Goal)

This is mostly noise! Indeed, helper_lemma P Q H1 H2 is equivalent to simply H2 – we only use the lemma for our Ltac tricks, and ideally, this should not appear in the final proof term. We can do better. The third idea is to isolate the messy proof term containing helper_lemma, and simplify it after it has been produced by counting the exists. Isolating the proof term can be achieved with the following pattern:

  let n := constr:(ltac:(mytactic) : nat) in
  ...

constr:() and ltac:() are both quotations: the first one indicates that its contents must be parsed as a Coq term, and the second one that it must be parsed as a tactic. Their combination above indicates that we want to produce a term (of type nat), and to run the tactic mytactic to produce it.

mytactic will run on a goal of type nat, and the proof term it produces by proving this goal will become the definition of n. Let us replace mytactic by our counting tactic (its continuation being simply exact to prove the nat goal using the result of the count):

(* Goal:
   ====================================
     exists x y z : nat, x + y = z
*)

  match goal with |- ?G =>
    let n := constr:(ltac:(count_in_ty G ltac:(fun n => exact n)) : nat) in
    pose n
  end.

(* Goal:
   n := ((let n := 3 in
          helper_lemma (exists x y z : nat, x + y = z) nat
            (fun H : exists x y z : nat, x + y = z =>
             match H with
             | ex_intro _ x (ex_intro _ x0 (ex_intro _ _ _)) => I
             end) n)
         :
         nat) : nat
   ============================
   exists x y z : nat, x + y = z
*)

The messy proof-term is now part of the definition. We now just have to simplify it, e.g. using eval cbv in n:

  match goal with |- ?G =>
    let n := constr:(ltac:(count_in_ty G ltac:(fun n => exact n)) : nat) in
    let n := (eval cbv in n) in
    pose n
  end.

(* Goal:
   n := 3 : nat
   ============================
   exists x y z : nat, x + y = z
*)

  Show Proof.

(* Prints: (let n := 3 in ?Goal) *)

And there you have it! Here is the whole implementation of count_exists:

Ltac count_in_hyp H acc kont :=
  lazymatch type of H with
  | exists _, _ => destruct H as [? H]; count_in_hyp H (S acc) kont
  | _ => kont acc
  end.

Definition helper_lemma : forall P Q, (P -> True) -> Q -> Q :=
  fun P Q _ Q_proof => Q_proof.

Ltac count_in_ty G kont :=
  let n := fresh "n" in
  evar (n : nat);
  apply (helper_lemma G); [
    let H := fresh in
    intro H; count_in_hyp H 0 ltac:(fun x => instantiate (n := x));
    exact I
  | kont n ].

Ltac count_exists kont :=
  match goal with |- ?G =>
    let n := constr:(ltac:(count_in_ty G ltac:(fun n => exact n)) : nat) in
    let n := (eval cbv in n) in
    kont n
  end.

This time of the year is, just like Christmas time, a time for laughs and magic… although the magic we are talking about, in the OCaml community, is not exactly nice, nor beautiful. Let’s say that we are somehow akin to many religions: we know magic does exist , but that it is satanic and shouldn’t be introduced to children.

Introducing Just The Right Time (JTRT)

Let me first introduce you to the concept of ‘Just The Right Time’ [1]. JTRT is somehow a ‘Just In…

This time of the year is, just like Christmas time, a time for laughs and magic… although the magic we are talking about, in the OCaml community, is not exactly nice, nor beautiful. Let’s say that we are somehow akin to many religions: we know magic does exist , but that it is satanic and shouldn’t be introduced to children.

Introducing Just The Right Time (JTRT)

Let me first introduce you to the concept of ‘Just The Right Time’ [1]. JTRT is somehow a ‘Just In Time’ compiler, but one that runs at the right time, not at some random moment decided by a contrived heuristic.

How does the compiler know when that specific good moment occurs? Well, he doesn’t, and that’s the point: you certainly know far better. In the OCaml world, we like good performances, like any other, but we prefer predictable ones to performances that may sometimes be awesome, and sometimes really slow. And we are ready to trade off some annotations for better predictability (or is it just me trying to give the impression that my opinion is everyone’s opinion…). Don’t forget that OCaml is a compiled language; hence the average generated code is good enough. Runtime compilation only matters for some subtle situations where a patterns gets repeated a lot, and you don’t know about that pattern before receiving some inputs.

Of course the tradeoff wouldn’t be the same in Javascript if you had to write something like that to get your code to perform decently.

function fact(n) {
   "compile this";
   if (n == 0) {
      "compile this too";
      return 1
   } else {
      "Yes, I really want to compile that";
      return (n * fact(n - 1););
   }
 }

The magical ‘this_is_the_right_time’ function

There are already nice tools for doing that in OCaml. In particular, you should look at metaocaml, which is an extension of the language that has been maintained for years. But it requires you to think a bit about what your program is doing and add a few types, here and there.

Fortunately, today is the day you may want to try this ugly weekend hack instead.

To add a bit of context, let’s say there are 1/ the Dirty Little Tricks, and 2/ the Other Kind of Ugly Hacks. We are presenting one of the latter; the kind of hacks for which you are both ashamed and a bit proud (but you should really be a lot more ashamed). I’ve made quite a few of those, and this one would probably rank well among the top 5 (and I’m deeply sorry about the other ones that are still in production somewhere…).

This is composed of two parts: a small compiler patch, and a runtime library. That library only exposes the following single function:

val this_is_the_right_time : 'a -> 'a

Let’s take an example:

let f x =
  let y = x + x in
  let g z = z * y in
  g

let multiply_by_six = f 3

You can ‘optimize’ it by changing it to:

let f x =
  let y = x + x in
  let g z = z * y in
  g

let multiply_by_six = this_is_the_right_time (f 3)

That’s all. By stating that this is the right time, you told the compiler to take that function and do its magic on it.

How the f**k does that work?!

The compiler patch is quite simple. It adds to every function some annotation to allow the compiler to know enough things about it. (It is annotated with its representation in the Flambda IR.) This is just a partial dump of the compiler memory state when transforming the Flambda IR to clambda. I tried to do it in some more ‘disciplined’ way (it used some magic to traverse the compiler internal memory representation to create a static version of it in the binary), but ‘ld’ was not so happy linking a ~500MB binary. So I went the ‘marshal’ way.

This now means that at runtime the program can find the representation of the closures. To give an example of the kind of code you really shouldn’t write, here is the magic invocation to retrieve that representation:

 let extract_representation_from_closure (value:'a)
                                 : Flambda.set_of_closures =
   let obj = Obj.repr value in
   let size = Obj.size obj in
   let id = Obj.obj (Obj.field obj (size - 2)) in
   let marshalled = Obj.field obj (size - 1) in
   (Marshal.from_string marshalled 0).(id)

With that, we now know the layout of the closure and we can extract all the variables that it binds. We can further inspect the value of those bound variables, and build an IR representation for them. That’s the nice thing about having an untyped IR, you can produce some even when you lost the types. It will just probably be quite wrong, but who cares…

Now that we know everything about our closure, we can rebuild it, and so will we. As we can’t statically build a non-closed function (the flambda IR happens after closure conversion), we will instead build a closed function that allocates the closure for us. For our example, it would look like this:

 let build_my_closure previous_version_of_the_closure =
   let closure_field_y = previous_version_of_the_closure.y in
   fun z -> z * 6 (* closure_field_y * closure_field_y *)

In that case the function that we are building is closed, so we don’t need the old closure to extract its field. But this shows the generic pattern. This would be used like that:

 let this_is_the_right_time optimize_this =
   let ir_version = extract_representation_from_closure optimize_this in
   let build_my_closure = magic_building_function ir_version in
   build_my_closure optimize_this

I won’t go too much into the details of the ‘magic_building_function’, because it would be quite tedious. Let’s just say that it is using mechanisms provided for the native toplevel of OCaml.

A more sensible example

To finish on something a bit more interesting than ‘time_6’, let’s suppose that we designed a super nice language whose AST and evaluator are:

 type expr =
 | Add of expr * expr
 | Const of int
 | Var

let rec eval_expr expr x =
  match expr with
  | Add (e1, e2) -> eval_expr e1 x + eval_expr e2 x
  | Const i -> i
  | Var -> x

But we want to optimize it a bit, and hence wrote a super powerful pass:

 let rec optimize expr =
   match expr with
   | Add (Const n1, Add (e, Const n2)) -> Add (Const (n1 + n2), optimize e)
   | Add (e1, e2) -> Add (optimize e1, optimize e2)
   | _ -> expr

The user writes some expression, that gets parsed to Add (Const 11, Add (Var, Const 22)), it goes through optimizing and results in Add (Const 33, Var). Then you find that this looks like the right time.

let optimized =
   this_is_the_right_time 
        (fun x -> (eval_expr (optimize user_ast) x))

Annnnd… nothing happens. The reason being that there is no way to distinguish between mutable and immutable values at runtime, hence the safe assumption is to assume that everything is mutable, which limits optimizations a lot. So let’s enable the ‘special’ mode:

incorrect_mode := true

And MAGIC happens! The code that gets spitted out is exactly what we want (that is fun x -> 33 + x).

Conclusion

Just so that you know, I don’t really recommend using it. It’s buggy, and many details are left unresolved (I suspect that the names you would come up for that kind of details would often sound like ‘segfault’). Flambda was not designed to be used that way. In particular, there are some invariants that must be maintained, like the uniqueness of variables and functions… that we completely disregarded. That lead to some ‘funny’ behaviors (like ‘power 2 8′ returning 512…). It is possible to do that correctly, but that would require far more than a few hours’ hacking. This might be a lot easier with the upcoming version of Flambda.

So this is far from ready, and it’s not going to be anytime soon (supposing that this is a good idea, which I’m still not convinced it is).

But if you still want to play with it: the sources are available.

[1] Not that it exists in real-world.

A new release of Alt-Ergo (version 2.1.0) is available on Alt-Ergo’s website: https://alt-ergo.ocamlpro.com/#releases. An OPAM package for it will be published soon.
In this release, we mainly improved the CDCL-based SAT solver to get performances similar to/better than the old Tableaux-like SAT. The CDCL solver is now the default Boolean reasoner. The full list of CHANGES is available here.
Despite our various tests, you may still encounter some issues with this new solver.  Please, don&…

A new release of Alt-Ergo (version 2.1.0) is available on Alt-Ergo’s website: https://alt-ergo.ocamlpro.com/#releases. An OPAM package for it will be published soon.
In this release, we mainly improved the CDCL-based SAT solver to get performances similar to/better than the old Tableaux-like SAT. The CDCL solver is now the default Boolean reasoner. The full list of CHANGES is available here.
Despite our various tests, you may still encounter some issues with this new solver.  Please, don’t hesitate to report bugs, ask questions, and give your feedback!

Update – TZScan.io can now work on top of the zeronet (zeronet.tzscan.io), we hope it can help the developers community monitor the network. You can now switch between the alphanet & zeronet networks!

OCamlPro is pleased to announce an update of TzScan (http://tzscan.io), its Tezos block explorer to ease the use of the Tezos network.

In addition to some minor bugfixes, the main novelties are:

• Health of the network with stats about the blocks, endorsements, bakers, etc.
• Display of futu…

Update – TZScan.io can now work on top of the zeronet (zeronet.tzscan.io), we hope it can help the developers community monitor the network. You can now switch between the alphanet & zeronet networks!

OCamlPro is pleased to announce an update of TzScan (http://tzscan.io), its Tezos block explorer to ease the use of the Tezos network.

In addition to some minor bugfixes, the main novelties are:

• Health of the network with stats about the blocks, endorsements, bakers, etc.
• Display of future baker’s rights in the current cycle
• For each account, a more detailed balance including the bonds, rewards, fees, etc. for the current cycle and its future baking positions
• A new feature to inject signed operations in the network
• In the detailed block’s view, all blocks are displayed at the same level in alternative chains
• UI improvements on desktop, tablet and mobile

We are still working hard trying to improve and add new features to TzScan. Further enhancements and optimizations are to come. Enjoy and play with our explorer.

If you have suggestions or bugs, please send us reports at contact@tzscan.io

OCamlPro is proud to release a first version of TzScan (http://tzscan.io), its Tezos
block explorer to ease the use of the Tezos network.

What TzScan can do for you :

– Several charts on blocks, operations, network, volumes, fees, and more,
– Marketcap and Futures/IOU prices from coinmarket.com,
– Blocks, operations, accounts and contracts detail pages,
– Public API to get information about blocks, operations, accounts and more,
– Documentation on different concept…

OCamlPro is proud to release a first version of TzScan (http://tzscan.io), its Tezos
block explorer to ease the use of the Tezos network.

What TzScan can do for you :

– Several charts on blocks, operations, network, volumes, fees, and more,
– Marketcap and Futures/IOU prices from coinmarket.com,
– Blocks, operations, accounts and contracts detail pages,
– Public API to get information about blocks, operations, accounts and more,
– Documentation on different concepts of Tezos like Endorsements, Nonces, etc.

What we tried to do with TzScan is to show differently the Tezos network to have a better understanding of what is really going on by showing the main points of Proof of Stake. Further enhancements and optimization are to come but enjoy and play with our explorer.

If you have suggestions or bugs, please send us reports at contact@tzscan.io !

As a tradition, we took part in this year’s Journées Francophones des Langages Applicatifs (JFLA 2018) that was chaired by LRI’s Sylvie Boldo and hosted in Banyuls the last week of January. That was a nice opportunity to present a live demo of a multisignature smart-contract entirely written in the #Liquidity language designed at OCamlPro, and deployed live on the Tezos alphanet (the slides are now available, see at the end of the post).

Tezos is the only blockchain to use a strong…

As a tradition, we took part in this year’s Journées Francophones des Langages Applicatifs (JFLA 2018) that was chaired by LRI’s Sylvie Boldo and hosted in Banyuls the last week of January. That was a nice opportunity to present a live demo of a multisignature smart-contract entirely written in the #Liquidity language designed at OCamlPro, and deployed live on the Tezos alphanet (the slides are now available, see at the end of the post).

Tezos is the only blockchain to use a strongly typed, functional language, with a formal semantic and an interpreter validated by the use of GADTs (generalized abstract data-types). This stack-based language, named Michelson, is somewhat tricky to use as-is, the absence of variables (among others) necessitating to manipulate the stack directly. For this reason, we have developed, starting in June 2017, a higher level language, Liquidity, implementing the type system of Michelson in a subset of OCaml.

In addition to the compiler which allows to compile Liquidity programs to Michelson ones, we have developed a decompiler which, from Michelson code, can recover a Liquidity version, much easier to look at and understand (for humans). This tool is of some significance considering that contracts will be stored on the blockchain in Michelson format, making them more approachable and understandable for end users.

To facilitate designing contracts and foster Liquidity adoption we have also developed a web application. This app offers somewhat bare-bone editors for Liquidity and Michelson, allows compilation in the browser directly, deployment of Liquidity contracts and interaction with them (using the Tezos alphanet).

This blog post presents these different tools in more detail.

Michelson

Michelson is a stack-based, functional, statically and strongly typed language. It comes with a set of built-in base types like strings, Booleans, unbounded integers and naturals, lists, pairs, option types, union (of two) types, sets, maps. There also a number of domain dependent types like amounts (in tezzies), cryptographic keys and signatures, dates, etc. A Michelson program consists in a structured sequence of instructions, each of which operates on the stack. The program takes as inputs a parameter as well as a storage and returns a result and a new value for the storage. They can fail at runtime with the instruction FAIL, or another error (call of a failing contract, out of gas, etc.), but most instructions that could fail return an option instead (e.g. EDIV returns None when dividing by zero). The following example is a smart contract which implements a voting system on the blockchain. The storage consists in a map from possible votes (as strings) to integers counting number of votes. A transaction to this contract must be made with an amount (accessible with instruction AMOUNT) greater or equal to 5 tezzies and a parameter which is a valid vote. If one of these conditions is not respected, the execution, and thus the transaction, fail. Otherwise the program retrieves the previous number of votes in the storage and increments them. At the end of the execution, the stack contains the pair composed of the value Unit and the updated map (the new storage).

parameter string;
storage (map string int);
return unit;
code
  { # Pile = [ Pair parameter storage ]
    PUSH tez "5.00"; AMOUNT; COMPARE; LT;
    IF # Is AMOUNT < 5 tz ?
      { FAIL }
      {
        DUP; DUP; CAR; DIP { CDR }; GET; # GET parameter storage
        IF_NONE # Is it a valid vote ?
          { FAIL }
          { # Some x, x now in the stack
            PUSH int 1; ADD; SOME; # Some (x + 1)
            DIP { DUP; CAR; DIP { CDR } }; SWAP; UPDATE;
            # UPDATE parameter (Some (x + 1)) storage
            PUSH unit Unit; PAIR; # Pair Unit new_storage
          }
      };
  }

Michelson has several specificities:

• Typing a Michelson program is done by types propagation, and not à la Milner. Polymorphic types are forbidden and type annotations are required when a type is ambiguous (e.g. empty list).
• Functions (lambdas) are pure and are not closures, i.e. they must have an empty environment. For instance, a function passed to another contract as parameter acts in a purely functional way, only accessing the environment of the new contract.
• Method calls is preformed with the instruction TRANSFER_TOKENS: it requires an empty stack (not counting its arguments). It takes as argument the current storage, saves it before the call is made, and finally returns it after the call together with the result. This forces developers to save anything worth saving in the current storage, while keeping in mind that a reentring call can happend (the returned storage might be different).

We won’t explain the semantics of Michelson here, a good one in big step form is available here.

The Liquidity Language

Liquidity is also a functional, statically and strongly typed language that compiles down to the stack-based language Michelson. Its syntax is a subset of OCaml and its semantic is given by its compilation schema. By making the choice of staying close to Michelson in spirit while offering higher level constraints, Liquidity allows to easily write legible smart contracts with the same safety guaranties offered by Michelson. In particular we decided that it was important to keep the purely functional aspect of the language so that simply reading a contract is not obscured by effects and global state. In addition, the OCaml syntax makes Liquidity an immediately accessible tool to programmers who already know OCaml while its limited span makes the learning curve not too steep.

The following example is a liquidity version of the vote contract. Its inner workings are rather obvious for anyone who has already programmed in a ML-like language.

[%%version 0.15]

type votes = (string, int) map

let%init storage (myname : string) =
  Map.add myname 0 (Map ["ocaml", 0; "pro", 0])

let%entry main
    (parameter : string)
    (storage : votes)
  : unit * votes =

  let amount = Current.amount() in

  if amount < 5.00tz then
    Current.failwith "Not enough money, at least 5tz to vote"
  else
    match Map.find parameter storage with
    | None -> Current.failwith "Bad vote"
    | Some x ->
        let storage = Map.add parameter (x+1) storage in
        ( (), storage )

A Liquidity contract starts with an optional version meta-information. The compiler can reject the program if it is written in a too old version of the language or if it is itself not recent enough. Then comes a set of type and function definitions. It is also possible to specify an initial storage (constant, or a non-constant storage initializer) with let%init storage. Here we define a type abbreviation votes for a map from strings to integers. It is the structure that we will use to store our vote counts.

The storage initializer creates a map containing two bindings, "ocaml" to 0 and "pro" to 0 to which we add another vote option depending on the argument myname given at deploy time.

The entry point of the program is a function main defined with a special annotation let%entry. It takes as arguments a call parameter (parameter) and a storage (storage) and returns a pair whose first element is the result of the call, and second element is a potentially modified storage.

The above program defines a local variable amount which contains the amount of the transaction which generated the call. It checks that it is greater than 5 tezzies. If not, we fail with an explanatory message. Then the program retrieves the number of votes for the chosen option given as parameter. If the vote is not a valid one (i.e., there is no binding in the map), execution fails. Otherwise, the current number of votes is bound to the name x. Storage is updated by incrementing the number of votes for the chosen option. The built-in function Map.add adds a new binding (here, it replaces a previously existing binding) and returns the modified map. The program terminates, in the normal case, on its last expression which is its returned value (a pair containing () — the contract only modifies the storage — and the storage itself).

A reference manual for Liquidity is available here. It gives a relatively complete overview of the available types, built-in functions and constructs of the language.

Compilation

Encodings

Because Liquidity is a lot richer than Michelson, some types and constructs must be simplified or encoded. Record types are translated to right-associated pairs with as many components as the record has fields. t1 is encoded as t1' in the following example.

type t1 = { a: int; b: string; c: bool}
type t1’ = (int * (string * bool))

Field accesses in a record is translated to accesses in the corresponding tuples (pairs). Sum (or union) types are translated using the built-in variant type (this is the or type in Michelson). t2 is encoded as t2' in the following example.

type ('a, 'b) variant = Left of 'a | Right of `b

type t2 = A of int | B of string | C
type t2’ = (int, (string, unit) variant) variant

Similarly, pattern matching on expressions of a sum type is translated to nested pattern matchings on variant typed expressions. An example translation is the following:

match x with
| A i -> something1(i)
| B s -> something2(s)
| C -> something3

match x with
| Left i -> something1(i)
| Right r -> match r with
             | Left s -> something2(s)
             | Right -> something3

Liquidity also supports closures while Michelson only allows pure lambdas. Closures are translated by lambda-lifting, i.e. encoded as pairs whose first element is a lambda and second element is the closure environment. The resulting lambda takes as argument a pair composed of the closure’s argument and environment. Adequate transformations are also performed for built-in functions that take lambdas as arguments (e.g. in List.map) to allow closures instead.

Compilation schema

This little section is a bit more technical, so if you don’t care how Liquidity is compiled precisely, you can skip over to the next one.

We note by Γ, [|x|]_d ⊢ X ↑^t compilation of the Liquidity instruction x, in environment Γ. Γ is a map associating variable names to a position in the stack. The compilation algorithm also maintains the size of the current stack (at compilation of instruction x), denoted by d in the previous expression. Below is a non-deterministic version of the compilation schema, the one implemented in the Liquidity compiler being a determinized version.

The result of compiling x is a Michelson instruction (or sequence of instructions) X together with a Boolean transfer information t. The instruction Contract.call (or TRANSFER_TOKENS in Michelson) needs an empty stack to evaluate, so the compiler empties the stack before translating this call. However, the various branches of a Michelson program must have the same stack type. This is why we need to maintain this information so that the compiler can empty stacks in some parts of the program.

Some of the rules have parts annotated with ?_b. This suffix denotes a potential reset or erasing. In particular:

• For sets, Γ?_b is ∅ if b evaluates to false, and Γ otherwise.
• For integers, d?_b is 0 if b evaluates to false, and d otherwise.
• For instructions, (X)?_b is {} if b evaluates to false, and X otherwise.

For instance, by looking at rule CONST, we can see that compiling a Liquidity constant simply consists in pushing this constant on the stack. To handle variables in a simple manner, the rule VAR tells us to look in the environment Γ for the index associated to the variable we want to compile. Then, instruction D(U)ⁱP puts at the top of the stack a copy of the element present at depth i. Variables are added to Γ with the Liquidity instruction let ... in or with any instruction that binds an new symbol, like fun for instance.

Decompilation from Michelson

While Michelson programs are high level compared to other bytecodes, it remains difficult for a blockchain end-user to understand what a Michelson program does exactly by looking at it. However, following the idea that “code is law”, a user should be able to read a contract and understand its precise semantic. Thus, we have developed a decompiler from Michelson to Liquidity, which allows to recover a much more readable and understandable representation of a program on the blockchain.

The decompilation of Michelson code follows the diagram below where:

• Cleaning consists in simplifying Michelson code to accelerate the whole process and simplify the following task. For now it consists in ereasing instructions whose continuation is a failure.
• Symbolic Execution consists in executing the Michelson program with symbolic inputs, and by replacing every value placed in the stacj by a node containing the instruction that generated it. Each node of this graph can be seen as an expression of the target program, which can be bound to a variable name. Edges to this node represent future occurrences of this variable.
• Decompilation consists in transforming the graph generated by the previous step in a Liquidity syntax tree. Names for variables are recovered from annotations produced by the Liquidity compiler (in case we decompile a Michelson program that was generated from Liquidty), or are chosen on the fly when no annotation is present (e.g. if the Michelson program was written by hand).

Finally the program is typed (to ensure no mistakes were made), simplified and pretty printed.

Example of decompilation

parameter bool;
return int;
storage int;
code {DUP; CAR;
      DIP { CDR; PUSH int 1 };  # stack is: parameter :: 1 :: storage
      IF # if parameter = true
         { DROP; DUP; }         # stack is storage :: storage
         { }                    # stack is 1 :: storage
         ;
      PAIR;
     }

This example illustrate some of the difficulties of the decompilation process: Liquidity is a purely functional language where each construction is an expression returning a value; Michelson handles the stack directly, which is impossible to concretize in in Liquidity (values in the stack don’t have the same type, as opposed to values in a list). In this example, depending on the value of parameter the contract returns either the content of the storage, or the integer 1. In the Michelson code, the programmer used the instruction IF, but its branches do not return a value and only operates by modifying (or not) the stack.

[%%version 0.15]
type storage = int
let%entry main (parameter : bool) (storage : storage) : (int * storage) =
    ((if parameter then storage else 1), storage)

The above translation to Liquidity also contains an if, but it has to return a value. The graph below is the result of the symbolic execution phase on the Michelson program. The IF instruction is decomposed in several nodes, but does not contain any remaining instruction: the result of this if is in fact the difference between the stack resulting from the execution of the then branch and from the else branch. It is denoted by the node N_IF_END_RESULT 0 (if there were multiple of these nodes with different indexes, the result of the if would have been a tuple, corresponding to the multiple changes in the stack).

Try-Liquidity

You can go to http://liquidity-lang.org/edit to try out Liquidity in your browser.

The first thing to do (if you want to deploy and interact with a contract) is to go into the settings menu. There you can set your Tezos private key (use one that you generated for the alphanet for the moment) or the source (i.e. your public key hash, which is derived from your private key if you set it).

You can also change which Tezos node you want to interact with (the first one should do, but you can also set one of your choosing such as one running locally on your machine). The timestamp shown next to the node name indicates how long ago was produced the last block that it knows of. Transactions that you make on a node that is not synchronized will not be included in the main chain.

You should now see your account with its balance in the top bar:

In the main editor window, you can select a few Liquidity example contracts or write your own. For this small tutorial, we will select multisig.liq which is a minimal multi-signature wallet contract. It allows anyone to send money to it, but it requires a certain number of predefined owners to agree before making a withdrawal.

Clicking on the button Compile should make the editor blink green (when there are no errors) and the compiled Michelson will appear on the editor on the right.

Let’s now deploy this contract on the Tezos alphanet. By going into the Deploy (or paper airplane icon) tab, we can choose our set of owners for the multisig contract and the minimum number of owners to be in agreement before a withdrawal can proceed. Here I put down two account addresses for which I possess the private keys, and I want the two owners to agree before any transaction is approved (2p is the natural number 2).

Then I can either forge the deployment operation which is then possible to sign offline and inject in the Tezos chain by other means, or I can directly deploy this contract (if the private key is set in settings). If deployment is successful, we can see both the deployment operation and the new contract on a block explorer by clicking on the provided links.

Now we can query the blockchain to examine our newly deployed contract. Head over to the Examine tab. The address field should already be filled with our contract handle. We just have to click on Retrieve balance and storage.

The contract has 3tz on its balance because we chose to initialize it this way. On the right is the current storage of the contract (in Liquidity syntax) which is a record with four fields. Notice that the actions field is an empty map.

Let’s make a few calls to this contract. Head over to the Call tab and fill-in the parameter and the amount. We can send for instance 5.00tz with the parameter Pay. Clicking on the button Call generates a transaction which we can observe on a block explorer. More importantly if we go back to the Examine tab, we can now retrieve the new information and see that the storage is unchanged but the balance is 8.00tz.

We can also make a call to withdraw money from the contract. This is done by passing a parameter of the form:

Manage (
  Some {
    destination = tz1brR6c9PY3SSfBDu7Qxdhsz3pvNRDwf68a;
    amount = 2tz;
})

This is a proposition of transfer of funds in the amount of 2.00tz from the contract to the destination tz1brR6c9PY3SSfBDu7Qxdhsz3pvNRDwf68a.

The balance of the contract has not changed (it is still 8.00tz) but the storage has been modified. That is because this multisig contract requires two owners to agree before proceeding. The proposition is stored in the map actions and is associated to the owner who made said proposition.

{
  owners =
    (Set
       [tz1XT2pgiSRWQqjHv5cefW7oacdaXmCVTKrU;
       tz1brR6c9PY3SSfBDu7Qxdhsz3pvNRDwf68a]);
  actions =
    (Map
       [(tz1brR6c9PY3SSfBDu7Qxdhsz3pvNRDwf68a,
          {
            destination = tz1brR6c9PY3SSfBDu7Qxdhsz3pvNRDwf68a;
            amount = 2.00tz
          })]);
  owners_length = 2p;
  min_agree = 2p
}

We can now open a new browser tab and point it to http://liquidity-lang.org/edit, but this time we fill in the private key for the second owner tz1XT2pgiSRWQqjHv5cefW7oacdaXmCVTKrU. We choose the multisig contract in the Liquidity editor and fill-in the contract address in the call tab with the same one as in the other session TZ1XvTpoSUeP9zZeCNWvnkc4FzuUighQj918 (you can double check the icons for the two contracts are identical). For the the withdrawal to proceed, this owner has to make the exact same proposition so let’s make a call with the same parameter:

Manage (
  Some {
    destination = tz1brR6c9PY3SSfBDu7Qxdhsz3pvNRDwf68a;
    amount = 2tz;
})

The call should also succeed. When we examine the contract, we can now see that its balance is down to 6.00tz and that the field actions of its storage has been reinitialized to the empty map. In addition, we can update the balance of our first account (by clicking on the circle arrow icon in the tob bar) to see that it is now up an extra 2.00tz and that was the destination of the proposed (and agreed on) withdrawal. All is well!

We have seen how to compile, deploy, call and examine Liquidity contracts on the Tezos alphanet using our online editor. Experiment with your own contracts and let us know how that works for you!

• Slides in English
• and French

Now that the winter holiday break is over, we are starting to see the results of winter hacking among our community.

The first great hack for 2018 is from Sadiq Jaffer, who got OCaml booting on a tiny and relatively new CPU architecture -- the Espressif ESP32. After proudly demonstrating a battery powered version to the folks at OCaml Labs, he then proceeded to clean it up enough tha it can be built with a Dockerfile, so that others can start to do a native code port and get bindings to the net…

Now that the winter holiday break is over, we are starting to see the results of winter hacking among our community.

The first great hack for 2018 is from Sadiq Jaffer, who got OCaml booting on a tiny and relatively new CPU architecture -- the Espressif ESP32. After proudly demonstrating a battery powered version to the folks at OCaml Labs, he then proceeded to clean it up enough tha it can be built with a Dockerfile, so that others can start to do a native code port and get bindings to the networking interface working.

Read all about it on Sadiq's blog, and thanks for sharing this with us, Sadiq!

We also noticed that another OCaml generic virtual machine for even smaller microcontrollers has shown up on GitHub. This, combined with some functional metaprogramming, may mean that 2018 is the year of OCaml in all the tiny embedded things...

Since 2017 is just over, now is probably the best time to review what happened during this hectic year at OCamlPro… Here are our big 2017 achievements, in the world of blockchains (the Liquidity smart contract language, Tezos and the Tezos ICO,  etc.), of OCaml (with OPAM 2, flambda 2 etc.), and of formal methods (Alt-Ergo etc.)

Since 2017 is just over, now is probably the best time to review what happened during this hectic year at OCamlPro… Here are our big 2017 achievements, in the world of blockchains (the Liquidity smart contract language, Tezos and the Tezos ICO,  etc.), of OCaml (with OPAM 2, flambda 2 etc.), and of formal methods (Alt-Ergo etc.)