1102 lines
42 KiB
TeX
1102 lines
42 KiB
TeX
\documentclass[a4paper]{article}
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\usepackage[T1]{fontenc}
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\usepackage[utf8]{inputenc}
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\usepackage[a4paper]{geometry}
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%\usepackage[francais]{babel}
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%\usepackage{subfigure}
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%\usepackage{fancyvrb}
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%\usepackage{fancyhdr}
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\usepackage[]{hyperref}
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\usepackage{array}
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\usepackage{xcolor}
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%\usepackage{comment}
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%\usepackage{lmodern}
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\usepackage{varwidth}
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%\usepackage{tikz}
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%\usetikzlibrary{arrows}
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%\usetikzlibrary{automata}
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%\usetikzlibrary{matrix}
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%\usetikzlibrary{shapes}
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%\usetikzlibrary{positioning}
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\usepackage{macros}
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\usepackage{subfigure}
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% fontes tt avec gras (mots-clés)
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\renewcommand{\ttdefault}{txtt}
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\lstset{
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language=Heptagon,% numbers=left, numberstyle=\small,
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basicstyle=\normalsize\ttfamily,captionpos=b,
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frame={tb}, rulesep=1pt, columns=fullflexible,
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xleftmargin=1cm, xrightmargin=1cm,
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mathescape=true
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}
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\title{Heptagon/BZR manual}
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\author{}
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%\date{}
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\begin{document}
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\maketitle
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\section{Introduction and tutorial}
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\label{sec:intro}
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\subsection{Heptagon: short presentation}
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\label{sec:hept-short-pres}
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Heptagon is a synchronous dataflow language, with a syntax allowing the
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expression of control structures (e.g., switch or mode automata).
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A typical Heptagon program will take as input a sequence of values, and will
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output a sequence of values. Then, variables (inputs, outputs or locals) as well
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as constants are actually variable or constant \emph{streams}. The usual
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operators (e.g., arithmetic or Boolean operators) are applied pointwise on these
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sequences of values.
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For example, the Heptagon program below is composed of one node \texttt{plus},
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performing the pointwise sum of its two integer inputs:
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\begin{lstlisting}
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node plus(x:int,y:int) returns (z:int)
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let
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z = x + y;
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tel
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\end{lstlisting}
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\texttt{x} and \texttt{y} are the inputs of the node \texttt{plus}; \texttt{z}
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is the output. \texttt{x}, \texttt{y} and \texttt{z} are of type \texttt{int},
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denoting integer \emph{streams}. \texttt{z} is defined by the equation
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\lstinline|z = x + y|.
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An execution of the node \texttt{plus} can then be:
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\[
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\begin{streams}{5}
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x & 1 & 2 & 3 & 4 & \ldots\\\hline
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y & 1 & 2 & 1 & 2 & \ldots\\\hline
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\mathtt{plus}(x,y) & 2 & 4 & 4 & 6 & \ldots\\
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\end{streams}
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\]
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\subsection{Required tools}
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\label{sec:required-tools}
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The use of the Heptagon compiler by itself does not require any additional
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tools. However, the usual use involves a compiler for the generated code (e.g.,
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\texttt{gcc} for C generated code, or \texttt{javac} for Java).
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The tools below are optional or are related to some subparts of Heptagon:
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\begin{itemize}
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\item The graphical display tool \texttt{sim2chro} can be obtained from
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Verimag\footnote{\url{http://www-verimag.imag.fr/~raymond/edu/distrib/}}. It can
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be used together with the graphical simulator \texttt{hepts} (see Section~\ref{sec:simulation}).
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\item The \texttt{Sigali} tool for model-checking and discrete controller
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synthesis \cite{sigali}
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\footnote{\url{http://www.irisa.fr/vertecs/Logiciels/sigali.html}} is
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mandatory for the use of contracts (see
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Section~\ref{sec:extens-with-contr}). \texttt{Sigali} can be downloaded on the
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BZR website : \url{http://bzr.inria.fr}.
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\end{itemize}
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\subsection{Compilation and installation}
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\label{sec:comp-inst}
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\subsubsection{Required libraries and tools for the compilation}
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\label{sec:requ-libr-tools}
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The compilation of the Heptagon compiler requires:
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\begin{itemize}
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\item \texttt{OCaml}\footnote{\url{http://caml.inria.fr}} (version $\geq$
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3.11), and the \texttt{ocamlbuild} and \texttt{ocamlfind} tools
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\item the \texttt{Menhir}\footnote{\url{http://gallium.inria.fr/~fpottier/menhir/}} parser generator
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\item the \texttt{ocamlgraph}\footnote{\url{http://ocamlgraph.lri.fr}} library.
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\end{itemize}
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The compilation of the Heptagon simulator (optional) requires the
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\texttt{LablGTK2}\footnote{\url{http://wwwfun.kurims.kyoto-u.ac.jp/soft/lsl/lablgtk.html}}
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library.
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\subsubsection{Compilation}
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\label{sec:compilation}
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Once the compiler is downloaded and untarred, go into the \texttt{heptagon/}
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directory and type :
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\begin{alltt}
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> ./configure && make
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\end{alltt}
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This command will build the compiler, optionally the simulator (if the
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\texttt{LablGTK2} library is found), and the standard library.
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\subsubsection{Installation}
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\label{sec:installation}
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After the compilation, or the download and untar of the binary distribution, go
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into the \texttt{heptagon/} directory and type :
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\begin{alltt}
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> make install
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\end{alltt}
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By default, this will install the binaries (\texttt{heptc} and \texttt{hepts}) into
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\texttt{/usr/local/bin} and the standard library into
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\texttt{/usr/local/lib}. Consider the \texttt{configure} script options
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(\verb+./configure --help+) for other specific needs.
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\subsection{Heptagon programs compilation}
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\label{sec:hept-compilation}
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The Heptagon compiler is named \texttt{heptc}. Its list of options is available by
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:
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\begin{alltt}
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> heptc -help
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\end{alltt}
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Every options described below are cumulable.
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Assuming that the program to compile is in a file named \texttt{example.ept},
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then one can compile it by typing :
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\begin{alltt}
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> heptc example.ept
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\end{alltt}
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However, such compilation will only perform standard analysis (such as typing,
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causality, scheduling) and output intermediate object code, but not any final or
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executable code.
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The Heptagon compiler can thus generate code in some general languages, in order
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to obtain either a standalone executable, or a linkable library. The target
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language must then be given by the \texttt{-target} option:
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\begin{alltt}
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> heptc -target <language> example.ept
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\end{alltt}
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Where \texttt{<language>} is the name of the target language. For now, available
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languages are C (\texttt{c} option) and Java (\texttt{java} option).
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\subsection{Generated code}
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\label{sec:generated-code}
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The generic generated code consists, for each node, of two imperative functions:
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\begin{itemize}
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\item one ``reset'' function, used to reset the internal memory of the node;
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\item one ``step'' function, taking as input the nodes inputs, and whose call
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performs one step of the node, updates the memory, and outputs the nodes
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outputs.
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\end{itemize}
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A standard way to execute Heptagon program is to compile the generated files
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together with a main program of the following scheme :
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\begin{alltt}
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call the \textit{reset} function
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for each instant
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get the \textit{inputs} values
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\textit{outputs} \(\leftarrow\) \textit{step(inputs)}
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do something with \textit{outputs} values
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\end{alltt}
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Appendix~\ref{sec:app-generated-code} give specific technical details for each target language.
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\subsection{Simulation}
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\label{sec:simulation}
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A graphical simulator is available: \texttt{hepts}. It allows the user to simulate
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one node by providing a graphical window, where simulation steps can be
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performed by providing inputs of the simulated node.
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This simulator tool interacts with an executable, typically issued of Heptagon
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programs compilation, and which await on the standard input the list of the
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simulated node's inputs, and prints its outputs on the standard output. Such
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executable, for the simulation of the node \texttt{f}, can be obtained by the
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\texttt{-s <node>} option:
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\begin{alltt}
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> heptc -target c -s f example.ept
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\end{alltt}
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We can then directly compile the generated C program (whose main function stand
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in the \texttt{\_main.c} file):
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\begin{alltt}
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> cd example_c
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> gcc -Wall -c example.c
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> gcc -Wall -c _main.c
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> gcc -o f_sim _main.o example.o # \text{executable creation}
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\end{alltt}
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This executable \texttt{f\_sim} can then be used with the graphical simulator
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\texttt{hepts}, which takes as argument:
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\begin{itemize}
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\item The name of the module (capitalized name of the program without the
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\texttt{.ept} extension),
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\item the name of the simulated node,
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\item the path to the executable \texttt{f\_sim}.
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\end{itemize}
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\begin{alltt}
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> hepts -mod Example -node f -exec example_c/f_sim
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\end{alltt}
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\section{Syntax and informal semantics}
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\label{sec:synt-infor-sem}
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Heptagon programs are synchronous Moore machines, with parallel and hierarchical
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composition. The states of such machines define dataflow equations.
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\subsection{Nodes}
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\label{sec:nodes}
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Heptagon programs are structured in \emph{nodes}: a program is a sequence of
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nodes. A node is a subprogram with a name $f$, inputs $\ton{x}{,}$, outputs
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$\ton[1][p]{y}{,}$, local variables $\ton[1][q]{z}{,}$ and declarations
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$D$. $y_i$ and $z_i$ variables are to be defined in $D$, using operations
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between values of $x_j$, $y_j$, $z_j$. The declaration of one variable comes with its type
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($t_i$, $t'_i$ and $t''_i$ being the type of respectively $x_i$, $y_i$ and
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$z_i$).
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\begin{lstlisting}
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node f(x$_1$:t$_1$;$\ldots$;x$_n$:t$_n$) returns (y$_1$:t$'_1$,$\ldots$,y$_p$:t$'_p$)
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var z$_1$:t$''_1$,$\ldots$,z$_q$:t$''_q$;
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let
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D
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tel
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\end{lstlisting}
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Heptagon allows to distinguish, by mean of clocks and control structures (switch,
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automata), for declarations and expressions, the discrete instants of
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activation, when the declarations and expressions are computed and progress
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toward further states, and other instants when neither computation nor
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progression are performed.
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\subsection{Expressions}
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\label{sec:expressions}
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\subsubsection{Values and combinatorial operations}
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\label{sec:variables-constants}
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Heptagon is a dataflow language, i.e., every value, variable or constant, is
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actually a stream of value. The usual operators (e.g., arithmetic or Boolean
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operators) are applied pointwise on these sequences of values, as combinatorial
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operations (as opposed to \emph{sequential} operations, taking into account the
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current \emph{state} of the program: see delays in Section~\ref{sec:delays}).
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Thus, \texttt{x} denotes the stream $x_1.x_2.\ldots$, and \lstinline|x + y| is
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the stream defined by $($\lstinline|x + y|$)_i=x_i+y_i$.
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\[
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\begin{streams}{5}
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\mathtt{x} & x_1 & x_2 & x_3 & x_4 & \ldots\\\hline
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\mathtt{y} & y_1 & y_2 & y_3 & y_4 & \ldots\\\hline
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\mathtt{x + y} & x_1+y_1 & x_2+y_2 & x_3+y_3 & x_4+y_4 & \ldots\\
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\end{streams}
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\]
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\subsubsection{Delays}
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\label{sec:delays}
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Delays are the way to introduce some state in a Heptagon program.
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\begin{itemize}
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\item \lstinline|pre x| gives the value of \texttt{x} at the preceding
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instant. The value at the first instant is undefined.
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\item \lstinline|x -> y| takes the value of \texttt{x} at the first instant,
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and then the value of \texttt{y};
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\item \lstinline|x fby y| is equivalent to \lstinline|x -> pre y|.
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\end{itemize}
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\[
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\begin{streams}{3}
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\text{\lstinline|x|} & x_1 & x_2 & x_3 \\
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\hline
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\text{\lstinline|y|} & y_1 & y_2 & y_3 \\
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\hline
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\text{\lstinline|pre x|} & \perp & x_1 & x_2 \\
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\hline
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\text{\lstinline|x -> y|} & x_1 & y_2 & y_3 \\
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\hline
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\text{\lstinline|x fby y|} & x_1 & y_1 & y_2 \\
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\end{streams}
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\]
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Here is a small example of a node that sums its inputs:
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\begin{lstlisting}
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node sum(i:int) returns (o:int)
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let
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o = 0 fby (o + i)
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tel
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\end{lstlisting}
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\subsubsection{Clocks}
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It is possible to mix streams with different rates by having streams that are not present at each instant. This can be done using the \lstinline+when+ operator, that samples a stream according to a condition, either a boolean or an enumerated value. If \texttt{x} is a stream that is always present, then \lstinline+x when c+ (resp \lstinline+x when C(y)+) is a stream equal to \texttt{x} but only present when \texttt{c} is true (resp. \lstinline{y = C}). \lstinline+x whenot c+ is a shortcut for \lstinline+x when (not c)+. The \texttt{split} operator allows to sample a stream according to all possible values, i.e. \lstinline+split c (x) = x when c, x whenot c+ if \texttt{x} is a boolean and \lstinline+split y (x) = x when C1(y), .., x when Cp(y)+ if \texttt{y} has an enumerated type defined by \lstinline+type t = C1 | ... | Cp+.
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\[
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\begin{streams}{3}
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\text{\lstinline|x|} & x_1 & x_2 & x_3 \\
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\hline
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\text{\lstinline|c|} & true & false & true \\
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\hline
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\text{\lstinline|x when c|} & x_1 & . & x_3 \\
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\hline
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\text{\lstinline|y|} & C' & C & C' \\
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\hline
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\text{\lstinline|x when C(y)|} & . & x_2 & . \\
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\end{streams}
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\]
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The clock of an expression (resp. a stream) is a boolean stream that defines the instants when it is present. The clock of the streams that are always present is called \texttt{base} or \texttt{.}. If \texttt{x} has clock \texttt{ck}, denoted \lstinline+x :: ck+, then \lstinline+x when c+ has clock \lstinline{ck on c}.
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The \lstinline{merge} operator joins slow streams to create a faster stream.
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\[
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\begin{streams}{3}
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\text{\lstinline|c|} & true & false & true \\
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\hline
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\text{\lstinline|x|} & x_1 & . & x_3 \\
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\hline
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\text{\lstinline|y|} & . & y_2 & . \\
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\hline
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\text{\lstinline|merge c x y|} & x_1 & y_2 & x_3 \\
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\end{streams}
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\]
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\lstinline{merge} expects complementary streams. If \lstinline{z = merge c x y} and \lstinline+z :: ck+, then we must have \lstinline+x :: ck on c+ and \lstinline+y :: ck onot c+. It is thus different from \lstinline+if c then x else y+ that expects all its arguments to have the same clock. An analysis pass called \emph{clock calculus} checks that these conditions are met.
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Here is a first example of a bidirectional counter:
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\begin{lstlisting}
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type modes = Up | Down
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node two(m:modes;v:int) returns (o:int)
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var x:int;
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x_up:int :: . on Up(m);
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x_down:int :: . on Down(m);
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let
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o = 0 fby x;
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x_up = o when Up(m) + 1;
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x_down = o when Down(m) + 1;
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x = merge m (Up -> x_up) (Down -> x_down)
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tel
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\end{lstlisting}
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Note that clocks are inferred by the compiler, so the clocking annotations are optional.
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It is important to understand the interaction between sampling and delays. The value of a delay only changes when it is activated, that is, when its clock is true. As soon as a function \texttt{f} contains some delay operator, sampling its inputs is not equivalent to sampling its outputs, that is, \lstinline+f(x when c)+ $\neq$ \lstinline+(f x) when c+.
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\[
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\begin{streams}{4}
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\text{\lstinline|c|} & true & false & true & false \\
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\hline
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\text{\lstinline|counter(1)|} & 0 & 1 & 2 & 3 \\
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\hline
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\text{\lstinline|counter(1) when c|} & 0 & . & 2 & . \\
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\hline
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\text{\lstinline|counter(1 when c)|} & 0 & . & 1 & .\\
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\end{streams}
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\]
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\subsection{Declarations}
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\label{sec:declarations}
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A declaration $D$ can be either :
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\begin{itemize}
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\item an equation $x = e$, defining variable $x$ by the expression $e$ at each
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activation instants ;
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\item a node application $(\tonp{y}{,}) = f(\ton{e}{,})$, defining variables
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$\tonp{y}{,}$ by application of the node $f$ with values $\ton{e}{,}$ at each
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activation instants ;
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\item parallel declarations of $D_1$ and $D_2$, denoted $D_1\Pv D_2$.
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Variables defined in $D_1$ and $D_2$ must be
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exclusive. The activation of this parallel declaration activate both $D_1$ and
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$D_2$, which are both computed and both progress ;
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\item a switch control structure ;
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\item an automaton.
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\end{itemize}
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\subsubsection{Switch control structures}
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\label{sec:switch-contr-struct}
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The \texttt{switch} control structure allows to controls which equations are
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evaluated:
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\begin{lstlisting}
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type modes = Up | Down
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node two(m:modes;v:int) returns (o:int)
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var last x:int = 0;
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let
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o = x;
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switch m
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| Up do x = last x + v
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| Down do x = last x - v
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end
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tel
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\end{lstlisting}
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The \texttt{last} keyword defines a memory which is shared by the different
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modes. Thus, \lstinline|last x| is the value of the variable \texttt{x} in the
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previous instant, whichever was the activated mode.
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\subsubsection{Automata}
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\label{sec:automata}
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An automaton is a set of states (one of which being the initial one), and
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transitions between these states, triggered by Boolean expressions. A
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declaration is associated to each state. The set of variables defined by the
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automaton is the union, not necessarily disjoint (variables can have different
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definitions in different states, and can be partially defined : in this case,
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when the variable is not defined in an active state, the previous value of this
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variable is taken.
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At each automaton activation instant, one and only one state of this automaton
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|
is active (the initial one at the first activation instant). The declaration
|
|
associated to this active state is itself activated and progress in this
|
|
activation instant.
|
|
|
|
\paragraph{Example}
|
|
\label{sec:example}
|
|
|
|
The following example gives the node \texttt{updown}. This node is defined by the
|
|
automaton given in Figure~\ref{fig:updown-automaton}, composed of two states:
|
|
\begin{itemize}
|
|
\item the state \texttt{Up} gives to \texttt{x} its previous value augmented of 1
|
|
\item the state \texttt{Down} gives to \texttt{x} its previous value diminued of 1
|
|
\end{itemize}
|
|
This automaton comprises two transitions:
|
|
\begin{itemize}
|
|
\item it goes from \texttt{Up} (the initial state) to \texttt{Down} when
|
|
\texttt{x} becomes greater or equal than 10;
|
|
\item it goes from \texttt{Down} to \texttt{Up} when \texttt{x} becomes less or
|
|
equal 0.
|
|
\end{itemize}
|
|
|
|
\begin{figure}[htb]
|
|
\centering
|
|
\input{figures/updown-automaton}
|
|
\caption{Automaton of the \texttt{updown} node}
|
|
\label{fig:updown-automaton}
|
|
\end{figure}
|
|
|
|
\begin{lstlisting}
|
|
node updown() returns (y:int)
|
|
var last x:int = 0;
|
|
let
|
|
y = x;
|
|
automaton
|
|
state Up
|
|
do x = last x + 1
|
|
until x >= 10 then Down
|
|
state Down
|
|
do x = last x - 1
|
|
until x <= 0 then Up
|
|
end
|
|
tel
|
|
\end{lstlisting}
|
|
|
|
\[
|
|
\begin{streams}{9}
|
|
\text{current state} & Up & Up & \ldots & Up & Up & Down & Down & Down & \ldots\\\hline
|
|
\mathtt{y} & 1 & 2 & \ldots & 9 & 10 & 9 & 8 & 7 & \ldots\\\hline
|
|
\end{streams}
|
|
\]
|
|
|
|
Expressions on outgoing transitions of this active state are
|
|
evaluated, so as to compute the next active state : these are weak
|
|
transitions. Transitions are evaluated in declaration order, in the textual
|
|
syntax. If no transition can be triggered, then the current state is the next
|
|
active state.
|
|
|
|
\paragraph{Weak and strong transitions.}
|
|
|
|
Transitions between states can be of two types: weak transitions, and strong
|
|
ones.
|
|
|
|
\subparagraph{Weak transitions} are denoted $\Until e \Then S$. The meaning of
|
|
such transition is that when $e$ becomes true, the current state is executed
|
|
before leaving it. The target state is only executed at next instant.
|
|
|
|
\subparagraph{Strong transitions} are denoted $\Unless e \Then S$. When $e$
|
|
becomes true, the automaton instantly leaves the current state, and the target
|
|
state is executed.
|
|
|
|
For causality reasons, the condition on strong transitions cannot depend
|
|
instantly on the variables defined in the current state (as this state is not
|
|
known and can change because of these transitions). Therefore, the example of
|
|
the Figure~\ref{fig:updown-automaton} can be written as shown below:
|
|
|
|
\begin{lstlisting}
|
|
node updown() returns (y:int)
|
|
var last x:int = 0;
|
|
let
|
|
y = x;
|
|
automaton
|
|
state Up
|
|
do x = last x + 1
|
|
unless (last x >= 10) then Down
|
|
state Down
|
|
do x = last x - 1
|
|
unless (last x <= 0) then Up
|
|
end
|
|
tel
|
|
\end{lstlisting}
|
|
|
|
On this example, the sequence of states is exactly the same as in the previous
|
|
version; however, the transition from $Up$ to $Down$ is taken one instant after
|
|
(i.e., the instant next to the one where $x=10$). The resulting stream
|
|
$\mathtt{y}$ is the same:
|
|
|
|
\[
|
|
\begin{streams}{9}
|
|
\text{current state} & Up & Up & \ldots & Up & Up & Down & Down & Down & \ldots\\\hline
|
|
\mathtt{y} & 1 & 2 & \ldots & 9 & 10 & 9 & 8 & 7 & \ldots\\\hline
|
|
\end{streams}
|
|
\]
|
|
|
|
\paragraph{Transition and memory.}
|
|
When a transition (either weak or strong) denoted with \Then is taken, the
|
|
target state is reset in its initial state: such transitions are said
|
|
\emph{memoryless}. Conversely, \emph{transitions with memory} are denoted
|
|
$\Until e \Continue S$ (resp. $\Unless e \Continue S$): in that case, the target
|
|
state $S$ is executed without reset.
|
|
|
|
\subsection{Structured types}
|
|
|
|
\subsubsection{Arrays}
|
|
|
|
Arrays are denoted using the \lstinline+^+ symbol. For instance, \lstinline+int^10+ is the type of arrays of size 10 containing integers. Arrays can be multidimensional, like \lstinline{int^3^2}. One should note that indices appear in reverse order compared to C: \lstinline{int^3^2} should be understood as \lstinline{(int^3)^2}, that is an array of size 2 containing arrays of size 3 (this would have been written \lstinline{int t[2][3]} in C). \\
|
|
|
|
The following operators are defined for arrays:
|
|
\begin{itemize}
|
|
\item Accessing an element at a constant index: \lstinline{t[4]}
|
|
\item Accessing an element at a dynamic index with a default value: \lstinline{z = t.[x] default v} is a stream defined by $z_i = t_i[x_i]$ if $0 \leq x_i < n$ and $z_i = v_i$ otherwise (where $n$ is the size of \lstinline+t+).
|
|
\item Accessing an element at a truncated index: \lstinline+z = t[>x<]+ is defined by $z_i = t_i[\min(\max(0, x_i), n-1)]$ (where $n$ is the size of \lstinline+t+).
|
|
\item Modifying an element: \lstinline{t' = [ t with [x] = v ]} is a new array equal to \lstinline+t+, except for the element at index \lstinline+x+ which is equal to $v$, that is for all j in $[0, n-1]$ such that $j \neq x_i$, $t'_i[j] = t_i[j]$ and $t'_i[x_i] = v_i$.
|
|
\item Defining an array by copying one value: \lstinline+x^n+ is the array of size \lstinline+n+ whose elements are all equal to \lstinline+x+.
|
|
\item Defining an array explicitely: \lstinline+[1, x, 3, y, 5]+.
|
|
\item Extracting a slice: \lstinline+t[n..m]+ returns the sub array of \lstinline+t+ of size \lstinline{m-n+1} starting at index \lstinline+n+ and ending at index \lstinline+m+.
|
|
\item Concatening arrays: \lstinline+t1@t2+.
|
|
\end{itemize}
|
|
|
|
It is also possible to use \emph{iterators} to operate on arrays. For instance, one can add two arrays pointwise by doing \lstinline{t = map<<n>> (+)(t1, t2)} (where \lstinline+n+ is the size of \lstinline+t1+, \lstinline+t2+ and \lstinline+t+). The following iterators are defined:
|
|
\begin{itemize}
|
|
\item \lstinline+map+ applies a node pointwise to the input arrays and outputs one or several arrays. If \lstinline+f+ has type \lstinline+t1 * t2 -> t'1 * t'2+ then \lstinline+map<<n>> f+ has type \lstinline+t1^n * t2^n -> t'1^n * t'2^n+.
|
|
\item \lstinline+mapi+ is the same as \lstinline+map+ but the iterated function should expect another integer argument, which will be equal to the index of the inputs in the input arrays. If \lstinline+f+ has type \lstinline+t1 * t2 * int -> t'1 * t'2+ then \lstinline+map<<n>> f+ has type \lstinline+t1^n * t2^n -> t'1^n * t'2^n+.
|
|
\item \lstinline+fold+ iterates a node on an array accumulating values. If \lstinline+f+ has type \lstinline+t1 * t -> t+ then \lstinline+fold<<n>> f+ has type \lstinline+t1^n * t -> t+. For instance, \lstinline+fold<<2>> f(t, 0)+ is equivalent to \lstinline+f(t[1], f(t[0], 0))+.
|
|
\item \lstinline+foldi+ is to \lstinline+fold+ what \lstinline+mapi+ is to \lstinline+map+.
|
|
\item \lstinline+mapfold+ combines the result of \lstinline+map+ and \lstinline+fold+, by accumulating a value and outputting a new array. If \lstinline+f+ has type \lstinline+t1 * t -> t'1 * t+ then \lstinline+mapfold<<n>> f+ has type \lstinline+t1^n * t -> t'1^n * t+.
|
|
\end{itemize}
|
|
|
|
\begin{figure}[htp]
|
|
\centering
|
|
\subfigure[\texttt{map}]{
|
|
\includegraphics[width = 0.25\textwidth]{figures/map}
|
|
}
|
|
\subfigure[\texttt{fold}]{
|
|
\includegraphics[width = 0.25\textwidth]{figures/fold}
|
|
}
|
|
\subfigure[\texttt{mapfold}]{
|
|
\includegraphics[width = 0.25\textwidth]{figures/mapfold}
|
|
}
|
|
\caption{Iterators in \textsc{Heptagon}}
|
|
\label{fig:iterators}
|
|
\end{figure}
|
|
|
|
Iterators can also be used for multidimensional arrays. In the case of \lstinline+mapi+ and \lstinline+foldi+, the iterated function should then expect one argument for each dimension.
|
|
|
|
It is also possible to mimic partial application with iterators, by giving a list of arguments, not necessarily arrays, that will be given as first arguments to each application of the iterated function. For instance, \lstinline+o = map<<n>>f <(a)>(t)+ is equivalent to \lstinline+o[i] = f(a, t[i])+ for each element in the output array \lstinline+o+.
|
|
|
|
Arrays are semantically functional: each modification on an array creates a new array. Implementing these arrays using separate arrays can lead to very unefficient code. That's why an optimization pass called \emph{memory allocation}~\cite{Gerard:2012} tries to share arrays and avoid unnecessary copies within each node. It can be enabled using the \texttt{-memalloc} or \texttt{-O} option.
|
|
|
|
\subsubsection{Records}
|
|
|
|
The syntax for declaring record types is the following:
|
|
\begin{lstlisting}
|
|
type t = { f1: t1; f2: t2 }
|
|
\end{lstlisting}
|
|
Note that two different record types cannot have fields with the same name.
|
|
It is possible to declare a new record (\lstinline+{ f1 = x; f2 = 9 }+), read a field of a record (\lstinline+x.f1+) and modify one field (\lstinline+r' = { r with .f1 = v }+ returns a new record where all fields are equal to the ones in \lstinline+r+ except for \lstinline+f1+ which is equal to \lstinline+v+).
|
|
|
|
\subsubsection{Types alias}
|
|
|
|
It is possible to declare an alias for any type (like a \texttt{typedef} in C), for instance:
|
|
\begin{lstlisting}
|
|
type meter = int
|
|
type matrix = int^10^10
|
|
\end{lstlisting}
|
|
This alias can then be used anywhere a type is expected.
|
|
|
|
|
|
\subsection{Parametricity}
|
|
|
|
The size of arrays can be parametrized by so-called \emph{static expressions}, that is expressions that are reduced to constants at compile-time. They are either a literal, a global constant, a static parameter of a node or a static operation on two static expressions (\lstinline{+}, \lstinline{-}, \lstinline{*}, \lstinline{/}, \lstinline{+.}, \lstinline{<=}, \lstinline{or}, etc). Global constants are declared by:
|
|
\begin{lstlisting}
|
|
const n : int = 100
|
|
const t0 : float^n = 1.0^n
|
|
const r0 = { f1 = 0; f2 = t0 }
|
|
\end{lstlisting}
|
|
|
|
The parameters of a node are given between \lstinline+<<+ and \lstinline{>>} at the declaration of the node and are instantiated with the same syntax:
|
|
\begin{lstlisting}
|
|
node f<<m:int; t1: int^n>>(a:int^m) = (o:int^m)
|
|
let
|
|
o = map<<m>> (+)(a, t1);
|
|
tel
|
|
|
|
node g(a:int^n) = (o:int^n)
|
|
let
|
|
o = f<<n, t0>>(a);
|
|
tel
|
|
\end{lstlisting}
|
|
|
|
If the backend support parametricity (like in Java), static parameters are kept in the generated code. Otherwise, a pass of the compiler generates all the versions of the node that are needed. If a parametrized node defined in a file \texttt{f1.ept} is used in \texttt{f2.ept}, it is necessary to first compile \texttt{f1.ept} with the \texttt{-c} option (and without any \texttt{-target}), in order to generate a binary file \texttt{f1.epo}. The compilation of the second file, this time with the \texttt{-target} option, will generate code for all the necessary nodes, from \texttt{f1.ept} and \texttt{f2.ept}.
|
|
|
|
\subsection{Location annotations}
|
|
|
|
Memory allocation~\cite{Gerard:2012} avoids unnecessary array copies within the nodes automatically (it can be enable with the \texttt{-memalloc} or \texttt{-O} options). In order to avoid copies when calling nodes, the user must add \emph{location annotations}. We will give here only a short introduction, the interested reader can refer to~\cite{Gerard:2012} for more details. They express the fact that a function modifies in-place its argument. For instance, consider this node that swaps two elements in an array:
|
|
\begin{lstlisting}
|
|
node swap(i, j:int; t_in:float^100 at r) returns (t_out:float^100 at r)
|
|
var t_tmp:float^100 at r;
|
|
let
|
|
t_tmp = [ t_in with [i] = t_in[>j<] ];
|
|
t_out = [ t_tmp with [j] = t_in[>i<] ];
|
|
tel
|
|
\end{lstlisting}
|
|
The location annotations are introduced by the keyword \lstinline{at} followed by a location name. All the streams with the same location name are guaranteed to be stored together in the generated code, so the function generated for \texttt{swap} will directly modify its argument in-place.
|
|
|
|
Located variables are called \emph{semilinear}: they can only be updated once, but they can be read many times. An update is a function that modify its argument in-place, for instance a node that inputs and outputs located variables, and a read is any other function. For instance, modifying one element in an array is an update, but accessing one element is a read.
|
|
|
|
Only located variables can be given to a function that expects located arguments. A located variable can only be obtained by updating another located variable or by explicitly initializing a new location with the \lstinline+init+ construction:
|
|
\begin{lstlisting}
|
|
node shuffle(i_arr, j_arr : int^m; q : int) = (v : float)
|
|
var t, t_prev : float^n at r;
|
|
let
|
|
init<<r>> t_prev = t_0 fby t;
|
|
t = fold<<m>> swap(i_arr, j_arr, t_prev);
|
|
v = t[>q<];
|
|
tel
|
|
\end{lstlisting}
|
|
|
|
|
|
\subsection{Interfaces}
|
|
|
|
Interface files, with the extension \texttt{.epi}, do not contain any definition but only the declaration (or signatures) of nodes, types and constants. In particular, they are useful to import external functions. For instance:
|
|
\begin{lstlisting}
|
|
external fun sort(a:int^100) = (o:int^100)
|
|
\end{lstlisting}
|
|
The imported function should respect the calling convention given in appendix \ref{sec:app-generated-code}. See the directory \texttt{examples/extern\_C} for a complete example.
|
|
|
|
Interface files can be compiled with \texttt{heptc}, in order to obtain a
|
|
compiled interface (\texttt{.epci} file), necessary for the subsequent use of
|
|
the declared types and values in other Heptagon programs.
|
|
|
|
\subsection{Contracts for controller synthesis}
|
|
\label{sec:extens-with-contr}
|
|
|
|
Contracts are an extension of the Heptagon language, so as to allow to perform
|
|
discrete controller synthesis (DCS) on Heptagon programs. The extended language is
|
|
named BZR.
|
|
|
|
We associate to each node a \emph{contract}, which is a program associated with
|
|
two outputs :
|
|
\begin{itemize}
|
|
\item an output $e_A$ representing the environment model ;
|
|
\item an invariance objective $e_G$ ;
|
|
\item a set $\set{\ton{c}{,}}$ of controllable variables used for ensuring this objective.
|
|
\end{itemize}
|
|
|
|
This contract means that the node will be controlled, i.e., that values will be
|
|
given to $\ton{c}{,}$ such that, given any input trace yielding $e_A$, the
|
|
output trace will yield the true value for $e_G$.
|
|
|
|
Contracts are denoted :
|
|
\begin{lstlisting}
|
|
node f(x$_1$:t$_1$;$\ldots$;x$_n$:t$_n$) returns (y$_1$:t$'_1$;$\ldots$;y$_p$:t$'_p$)
|
|
contract
|
|
var $\ldots$
|
|
let
|
|
$\ldots$
|
|
tel
|
|
assume $e_A$
|
|
enforce $e_G$
|
|
with (c$_1$:t$''_1$;$\ldots$;c$_q$:t$''_n$)
|
|
|
|
var $\ldots$
|
|
let
|
|
y$_1$ = f$_1$($\ton{\mathtt{x}}{,},\ton[1][q]{\mathtt{c}}{,}$);
|
|
$\vdots$
|
|
y$_p$ = f$_p$($\ton{\mathtt{x}}{,},\ton[1][q]{\mathtt{c}}{,}$);
|
|
tel
|
|
\end{lstlisting}
|
|
|
|
\section{Example with Contracts: Multi-task System}
|
|
\label{sec:multi-task-system}
|
|
|
|
\subsection{Delayable Tasks}
|
|
\label{sec:delayable-tasks}
|
|
|
|
|
|
|
|
We consider a multi-task system composed of $n$ delayable
|
|
tasks. Figure~\ref{fig:del-task} shows a delayable task. A delayable task takes
|
|
three inputs \texttt{r}, \texttt{c} and \texttt{e}: \texttt{r} is the task
|
|
launch request from the environment, \texttt{e} is the end request, and
|
|
\texttt{c} is meant to be a controllable input controlling whether, on request,
|
|
the task is actually launched (and therefore goes in the active state), or
|
|
delayed (and then forced by the controller to go in the waiting state by stating
|
|
the false value to \texttt{c}). This node outputs a unique boolean \texttt{act}
|
|
which is true when the task is in the active state.
|
|
|
|
\begin{figure}[htb]
|
|
\begin{lstlisting}
|
|
node delayable(r,c,e:bool) returns (act:bool)
|
|
let
|
|
automaton
|
|
state Idle
|
|
do act = false
|
|
until r & c then Active
|
|
| a & not c then Wait
|
|
state Wait
|
|
do act = false
|
|
until c then Active
|
|
state Active
|
|
do act = true
|
|
until e then Idle
|
|
end
|
|
tel
|
|
\end{lstlisting}
|
|
\caption{Delayable task}
|
|
\label{fig:del-task}
|
|
\end{figure}
|
|
|
|
The Figure~\ref{fig:n-del-task} shows then a node \texttt{ntasks} where $n$
|
|
delayable tasks have been put in parallel. The tasks are inlined so as to be
|
|
able to perform DCS on this node, taking into account the tasks' states. Until
|
|
now, the only interest of modularity is, from the programmer's point of view, to
|
|
be able to give once the delayable task code.
|
|
|
|
\begin{figure}[htb]
|
|
\begin{lstlisting}
|
|
node ntasks($\ton{\mathtt{r}}{,},\ton{\mathtt{e}}{,}$:bool)
|
|
returns ($\ton{\mathtt{a}}{,}$:bool)
|
|
contract
|
|
let
|
|
ca$_{1}$ = a$_{1}$ & (a$_{2}$ or $\ldots$ or a$_{n}$);
|
|
$\vdots$
|
|
ca$_{n-1}$ = a$_{n-1}$ & a$_{n}$;
|
|
tel
|
|
enforce not (ca$_{1}$ or \ldots or ca$_{n-1}$)
|
|
with ($\ton{\mathtt{c}}{,}$:bool)
|
|
let
|
|
a$_{1}$ = inlined delayable(r$_{1}$,c$_{1}$,e$_{1}$);
|
|
$\vdots$
|
|
a$_{n}$ = inlined delayable(r$_{n}$,c$_{n}$,e$_{n}$);
|
|
tel
|
|
\end{lstlisting}
|
|
\caption{\texttt{ntasks} node: $n$ delayable tasks in parallel}
|
|
\label{fig:n-del-task}
|
|
\end{figure}
|
|
|
|
This \texttt{ntasks} node is provided with a contract, stating that its
|
|
composing tasks are exclusive, i.e., that there are no two tasks in the active
|
|
state at the same instant. This contract is enforced with the help of the
|
|
controllable inputs $c_i$.
|
|
|
|
\subsection{Contract composition}
|
|
\label{sec:contract-composition}
|
|
|
|
We want know to reuse the \texttt{ntasks} node, in order to build modularly a
|
|
system composed of $2n$ tasks. The Figure~\ref{fig:2n-del-task} shows the
|
|
parallel composition of two \texttt{ntasks} nodes. We associate to this
|
|
composition a new contract, which role is to enforce the exclusivity of the $2n$
|
|
tasks.
|
|
|
|
\begin{figure}[htb]
|
|
\begin{lstlisting}
|
|
node main($\ton[1][2n]{\mathtt{r}}{,},\ton[1][2n]{\mathtt{e}}{,}$:bool)
|
|
returns ($\ton[1][2n]{\mathtt{a}}{,}$:bool)
|
|
contract
|
|
let
|
|
ca$_{1}$ = a$_{1}$ & (a$_{2}$ or $\ldots$ or a$_{2n}$);
|
|
$\vdots$
|
|
ca$_{2n-1}$ = a$_{2n-1}$ & a$_{2n}$;
|
|
tel
|
|
enforce not (ca$_{1}$ or $\ldots$ or ca$_{2n-1}$)
|
|
let
|
|
($\ton{\mathtt{a}}{,}$) = ntasks($\ton{\mathtt{r}}{,}$,$\ton{\mathtt{e}}{,}$);
|
|
($\ton[n+1][2n]{\mathtt{a}}{,}$) = ntasks($\ton[n+1][2n]{\mathtt{r}}{,}$,$\ton[n+1][2n]{\mathtt{e}}{,}$);
|
|
tel
|
|
\end{lstlisting}
|
|
\caption{Composition of two \texttt{ntasks} nodes}
|
|
\label{fig:2n-del-task}
|
|
\end{figure}
|
|
|
|
It is easy to see that the contract of \texttt{ntasks} is not precise enough to
|
|
be able to compose several of these nodes. Therefore, we need to refine this
|
|
contract by adding some way to externally control the activity of the tasks.
|
|
|
|
\subsection{Contract refinement}
|
|
\label{sec:contract-refinement}
|
|
|
|
We first add an input \texttt{c}, meant to be controllable. The refined contract
|
|
will enforce that:
|
|
\begin{enumerate}
|
|
\item the tasks are exclusive,
|
|
\item one task is active only at instants when the input \texttt{c} is
|
|
true. This property, appearing in the contract, allow a node instantiating
|
|
\texttt{ntasks} to forbid any activity of the $n$ tasks instantiated.
|
|
\end{enumerate}
|
|
The Figure~\ref{fig:n-del-task-2} contains this new \texttt{ntasks} node.
|
|
|
|
\begin{figure}[htb]
|
|
\begin{lstlisting}
|
|
node ntasks(c,$\ton{\mathtt{r}}{,}$,$\ton{\mathtt{e}}{,}$:bool) returns ($\ton{\mathtt{a}}{,}$:bool)
|
|
contract
|
|
let
|
|
ca$_{1}$ = a$_{1}$ & (a$_{2}$ or $\ldots$ or a$_{n}$);$\ldots$
|
|
ca$_{n-1}$ = a$_{n-1}$ & a$_{n}$;
|
|
one = a$_{1}$ or $\ldots$ or a$_{n}$;
|
|
tel
|
|
enforce not (ca$_{1}$ or $\ldots$ or ca$_{n-1}$) & (c or not one)
|
|
with ($\ton{\mathtt{c}}{,}$:bool)
|
|
let
|
|
a$_{1}$ = inlined delayable(r$_{1}$,c$_{1}$,e$_{1}$);
|
|
$\vdots$
|
|
a$_{n}$ = inlined delayable(r$_{n}$,c$_{n}$,e$_{n}$);
|
|
tel
|
|
\end{lstlisting}
|
|
\caption{First contract refinement for the \texttt{ntasks} node}
|
|
\label{fig:n-del-task-2}
|
|
\end{figure}
|
|
|
|
\begin{figure}[htb]
|
|
\centering
|
|
\begin{lstlisting}
|
|
node ntasks(c,$\ton{\mathtt{r}}{,}$,$\ton{\mathtt{e}}{,}$:bool) returns ($\ton{\mathtt{a}}{,}$:bool)
|
|
contract
|
|
let
|
|
ca$_{1}$ = a$_{1}$ & (a$_{2}$ or $\ldots$ or a$_{n}$);$\ldots$
|
|
ca$_{n-1}$ = a$_{n-1}$ & a$_{n}$;
|
|
one = a$_{1}$ or $\ldots$ or a$_{n}$;
|
|
pone = false fby one;
|
|
tel
|
|
assume (not pone or c)
|
|
enforce not (ca$_{1}$ or $\ldots$ or ca$_{n-1}$) & (c or not one)
|
|
with ($\ton{\mathtt{c}}{,}$)
|
|
let
|
|
a$_{1}$ = inlined delayable(r$_{1}$,c$_{1}$,e$_{1}$);
|
|
$\vdots$
|
|
a$_{n}$ = inlined delayable(r$_{n}$,c$_{n}$,e$_{n}$);
|
|
tel
|
|
\end{lstlisting}
|
|
\caption{Second contract refinement for the \texttt{ntasks} node}
|
|
\label{fig:n-del-tasks-3}
|
|
\end{figure}
|
|
|
|
However, the controllability introduced here is know too strong. The synthesis
|
|
will succeed, but the computed controller, without knowing how \texttt{c} will
|
|
be instantiated, will actually block every tasks in their idle state. Indeed, if
|
|
the controller allows one task to go in its active state, the input \texttt{c}
|
|
can become false at the next instant, violating the property to enforce.
|
|
|
|
Thus, we propose to add an assumption to this contract: the input \texttt{c}
|
|
will not become false if a task was active an instant before. This new contract
|
|
is visible in Figure~\ref{fig:n-del-tasks-3}.
|
|
|
|
We can then use this new \texttt{ntasks} version for the parallel composition,
|
|
by instantiating the \texttt{c} input by a controllable variable and its
|
|
negation. This composition can be found in Figure~\ref{fig:ntasks-compos}.
|
|
|
|
\begin{figure}[htb]
|
|
\centering
|
|
\begin{lstlisting}
|
|
node main($\ton[1][2n]{\mathtt{r}}{,}$,$\ton[1][2n]{\mathtt{e}}{,}$:bool) returns ($\ton[1][2n]{\mathtt{a}}{,}$:bool)
|
|
contract
|
|
let
|
|
ca$_{1}$ = a$_{1}$ & (a$_{2}$ or $\ldots$ or a$_{2n}$);
|
|
$\vdots$
|
|
ca$_{2n-1}$ = a$_{2n-1}$ & a$_{2n}$;
|
|
tel
|
|
enforce not (ca$_{1}$ or $\ldots$ or ca$_{2n-1}$)
|
|
with (c:bool)
|
|
let
|
|
($\ton{\mathtt{a}}{,}$) = ntasks(c,$\ton{\mathtt{r}}{,}$,$\ton{\mathtt{e}}{,}$);
|
|
($\ton[n+1][2n]{\mathtt{a}}{,}$) = ntasks(\Not c,$\ton[n+1][2n]{\mathtt{r}}{,}$,$\ton[n+1][2n]{\mathtt{e}}{,}$);
|
|
tel
|
|
\end{lstlisting}
|
|
\caption{Two \texttt{ntasks} parallel composition}
|
|
\label{fig:ntasks-compos}
|
|
\end{figure}
|
|
|
|
\section{Known issues}
|
|
\label{sec:known-issues}
|
|
|
|
Heptagon is a research prototype. Users are kindly invited to submit bugs to the
|
|
Heptagon developers via \url{heptagon-developers@lists.}
|
|
|
|
Yet, the following subject are known to be issues for the current Heptagon
|
|
version:
|
|
\begin{itemize}
|
|
\item Discrete controller synthesis (DCS) can be applied only on full Boolean
|
|
programs (with static integer expressions). If applied on nodes containing
|
|
non-Boolean expressions or values, an abstraction will be computed, removing
|
|
every equation containing untranslatable value or expression. This abstraction
|
|
is conservative w.r.t. invariance properties, and does not jeopardize the use
|
|
of the computed controller, but this controller itself can be less efficient
|
|
due to the abstraction.
|
|
\item For the above reason, DCS does not mix well with array types, which will
|
|
be abstracted.
|
|
\item Translation to \texttt{Sigali} code (\texttt{-target z3z} option) for DCS
|
|
application activates the \texttt{-bool} option, for translation of enumerated
|
|
values into Boolean vectors. This translation cannot be applied on nodes whose
|
|
signature comprise enumerated clocks, e.g., the node \lstinline{filter} below:
|
|
|
|
\begin{lstlisting}
|
|
type t = A | B
|
|
|
|
node filter(x:int; c:t) returns (y:int on A(c))
|
|
let
|
|
y = x when A(c)
|
|
tel
|
|
\end{lstlisting}
|
|
|
|
\item Nodes whose signature comprise sampled streams cannot be inlined. However,
|
|
inlining of nodes comprising clocks without appearing in signature is
|
|
possible.
|
|
\end{itemize}
|
|
|
|
\clearpage
|
|
\appendix
|
|
|
|
\section{Generated code}
|
|
\label{sec:app-generated-code}
|
|
|
|
\subsection{C generated code}
|
|
\label{sec:c-generated-code}
|
|
|
|
C generated files from an Heptagon program \texttt{example.ept} are placed in a
|
|
directory named \texttt{example\_c}. This directory contains one file
|
|
\texttt{example.c}. For each node \texttt{f} of the source program, assuming
|
|
that \texttt{f} has inputs $(x_1:t_1,\ldots,x_n:t_n)$ and outputs
|
|
$(y_1:t'_1,\ldots,y_p:t'_p)$, $t_i$ and $t'_i$ being the data types of these
|
|
inputs and outputs, then the \texttt{example.c} file contains, for each node
|
|
\texttt{f}:
|
|
|
|
\begin{itemize}
|
|
\item A \texttt{Example\_\_f\_reset} function, with an argument \texttt{self} being a
|
|
memory structure instance:
|
|
|
|
\begin{lstlisting}[language=C]
|
|
void Example__f_reset(Example__f_mem* self);
|
|
\end{lstlisting}
|
|
|
|
\item A \texttt{Example\_\_f\_step} function, with as arguments the nodes inputs, a
|
|
structure \texttt{\_out} where the output will be put, and a memory structure
|
|
instance \texttt{self}:
|
|
|
|
\begin{lstlisting}[language=C]
|
|
void Example__f_step(t$_{1}$ x$_{1}$, ..., t$_{n}$ x$_{n}$,
|
|
Example__f_out* \_out,
|
|
Example__f_mem* self);
|
|
\end{lstlisting}
|
|
|
|
After the call of this function, the structure \texttt{\_out} contains the
|
|
outputs of the node:
|
|
\begin{lstlisting}[language=C]
|
|
typedef struct \{
|
|
t$'_1$ y$_{1}$;
|
|
...
|
|
t$'_p$ y$_{p}$;
|
|
\} Example__f_ans;
|
|
\end{lstlisting}
|
|
\end{itemize}
|
|
|
|
An example of main C code for the execution of this node would be then:
|
|
\begin{lstlisting}[language=C]
|
|
#include "example.h"
|
|
|
|
int main(int argc, char * argv[]) {
|
|
|
|
Example__f_m mem;
|
|
t$_{1}$ x$_{1}$;
|
|
...
|
|
t$_{n}$ x$_{n}$;
|
|
Example__f_out ans;
|
|
|
|
/* initialize memory instance */
|
|
f_reset(&mem);
|
|
|
|
while(1) {
|
|
/* read inputs */
|
|
scanf("...", &x$_{1}$, ..., &x$_{n}$);
|
|
|
|
/* perform step */
|
|
Example__f_step(x$_{1}$, ..., x$_{n}$, &ans, &mem);
|
|
|
|
/* write outputs */
|
|
printf("...", ans.y$_{1}$, ..., ans.y$_{p}$);
|
|
}
|
|
}
|
|
\end{lstlisting}
|
|
|
|
The above code is nearly what is produce for the simulator with the \texttt{-s}
|
|
option (see Section~\ref{sec:simulation}).
|
|
|
|
% \subsection{OCaml generated code}
|
|
% \label{sec:ocaml-generated-code}
|
|
|
|
|
|
% If the option \texttt{-target caml} is given, then the compiler generates OCaml
|
|
% code in a file named \texttt{example.ml}. Heptagon nodes are compiled into OCaml
|
|
% classes, where state variables are class properties, and the two functions
|
|
% ``reset'' and ``step'' are class methods. Thus, the class type of \texttt{f}
|
|
% would be:
|
|
% \begin{alltt}
|
|
% class f :
|
|
% object
|
|
% method reset : unit \(\rightarrow\) unit
|
|
% method step : t\ind{1} * ... * t\ind{n} \(\rightarrow\) (t\('\sb{1}\) * ... * t\('\sb{p}\))
|
|
% end
|
|
% \end{alltt}
|
|
|
|
\subsection{Java generated code}
|
|
\label{sec:java-generated-code}
|
|
|
|
Java generated files from an Heptagon program \texttt{example.ept} are placed in
|
|
a directory named \texttt{example\_java}. This directory contains one Java class
|
|
\texttt{f} (in the file \texttt{f.java}) for each node \texttt{f} of the source
|
|
program. Assuming that \texttt{f} has inputs $(x_1:t_1,\ldots,x_n:t_n)$ and
|
|
outputs $(y_1:t'_1,\ldots,y_p:t'_p)$, $t_i$ and $t'_i$ being the data types of
|
|
these inputs and outputs, then this \texttt{f} class implements the following
|
|
interface:
|
|
|
|
|
|
\begin{lstlisting}[language=Java]
|
|
public interface f {
|
|
|
|
public void reset();
|
|
|
|
public fAnswer step(t$_{1}$ x$_{1}$, ..., t$_{n}$ x$_{n}$);
|
|
}
|
|
\end{lstlisting}
|
|
|
|
The \texttt{fAnswer} class being a structure containing the outputs:
|
|
|
|
\begin{lstlisting}[language=Java]
|
|
public class fAnswer {
|
|
t$'\sb{1}$ y$_{1}$;
|
|
...
|
|
t$'\sb{p}$ y$_{p}$;
|
|
}
|
|
\end{lstlisting}
|
|
|
|
\bibliographystyle{plain}
|
|
\bibliography{manual}
|
|
|
|
|
|
\end{document}
|