Zélus is a synchronous language extended with Ordinary Differential Equations (ODEs) to program hybrid systems that mix discrete-time and continuous-time models. An example is a (discrete-time) model of a control software paired with a (continuous-time) model of the plant. The language shares the basic principles of the synchronous languages Lustre with modularity features from Lucid Synchrone (type inference, hierarchical automata, and higher-order functions). It is conservatively extended to write continuous-time models expressed by ODEs and zero-crossing events. The compiler is written in OCaml and is structured as a series of source-to-source and traceable transformations that ultimately yield statically scheduled sequential code. Continuous-time models are simulated using an off-the-shelf numerical solver (here Sundials CVODE and, for the moment, the two built-in solvers ode23 and ode45).
The easiest way to install Zelus is via Opam, the OCaml package manager.
$ opam install zelus
You can then test your installation with:
$ zeluc -version
The manual, examples, and research papers can be found at http://zelus.di.ens.fr
By default Zelus relies on the built-in solvers. To switch to Sundials CVODE you need to install sundialsml (which requires sundials). Some examples also depend on the zelus gtk library (which requires gtk2.0)
$ opam install sundialsml zelus-gtk
We also provide a dockerfile to setup an environment with all the dependencies. Build the image with (you might need to increase available memory in docker preferences):
$ make docker-build
Run with:
$ make docker-run
Consider the example of a bouncing ball. The zelus code is the following:
let loose = 0.8
let g = 9.81
let x0 = 0.0
let y0 = 10.0
let x'0 = 1.0
let y'0 = 0.0
let hybrid main () = () where
rec der x = x' init x0
and der y = y' init y0
and der x' = 0.0 init x'0
and der y' = -.g init y'0 reset up(-.y) -> -.loose *. last y'
and present up(-.y) -> local cpt in
do cpt = 0 fby cpt + 1
and () = print_endline (string_of_int cpt) done
The dynamics of the ball is expressed with four ODEs defining the position (x, y)
and the speed (x', y')
of the ball given an initial position (x0, y0)
and an initial speed (x'0, y'0)
.
Whenever the ball hits the ground up(-. y)
the discrete time code of the body of the present
construct is executed (here incrementing a simple counter).
The zeluc compiler takes a zelus file (e.g., bouncing.zls
) and compile it to OCaml code (e.g., bouncing.ml
).
$ zeluc bouncing.zls
You can also specify a simulation node.
The compiler then generates an additional file containing the simulation code (e.g., main.ml
).
$ zeluc -s main bouncing.zls
To build an executable, the last thing to do is to compile the OCaml code using the zelus
library.
$ ocamlfind ocamlc -linkpkg -package zelus bouncing.ml main.ml -o bouncing
This repository includes runnable examples demonstrating different aspects of the language.
The source code for several of the examples can be found in the examples
directory.
To build most of the examples:
$ cd examples && make
The executables can be found in each example directory (e.g., horloge/horloge_main.exe
).
First, you need to install [opam] (https://opam.ocaml.org) and
[dune] (https://dune.readthedocs.io/en/stable/).
Install sundials <= 6.1 (https://computing.llnl.gov/projects/sundials/sundials-software). Install sundialsml 6.1 from the source (https://inria-parkas.github.io/sundialsml/). Warning: as of Nov. 2023, sundialsml only works with sundials <= 6.1. We hare working on updating it with the latest version. Moreover, sundialsml only works with OCaml up to version 4.14.1. It does not work yet with OCaml version >= 5.0.
Everything should work then!
We use dune to build the compiler, the libraries, and the examples. To build the project:
$ ./configure
$ dune build
This produces two executables (and some tools in ./tools
):
compiler/zeluc.exe
: native codecompiler/zeluc.bc
: byte code (can be used with ocamldebug)
Libraries are split in two packages:
zelus
: the standard librarieszelus-gtk
: additional libraries that depend on lablgtk (only built if lablgtk is installed)
The build automatically detects if sundialsml is installed and updates the librairies accordingly.
The main Makefile contains useful commands to build the project of install zelus as an opam development package from source.
$ make help
Usage:
make all # Build the compiler and libraries
make test # Launch the tests via dune
make examples # Build all the examples
make tools # Build the tools
make install # Install as an opam development package pinned to this directory
make uninstall # Remove opam pin
make clean # Clean the entire project
make docker-build # Build the Docker image
make docker-run # Launch a terminal in the Docker image
make help # Print this help
To run all the tests you can use dune.
$ dune runtest
Or alternatively, the Makefile of the test directory.
$ cd test
$ make
Tests are split into 3 categories: good
, bad
, and run
.
To launch a single subset (e.g., good
):
$ cd good
$ make
To clean generated files:
$ make clean
@inproceedings{Zelus2013HSCC,
author = {Timothy Bourke and Marc Pouzet},
title = {Zélus: A Synchronous Language with {ODEs}},
booktitle = {16th International Conference on Hybrid Systems: Computation and Control (HSCC'13)},
pages = {113--118},
month = mar,
year = 2013,
}