Synchronous_reactive_systems/beamer/beamer.tex

\documentclass{beamer}
\usepackage{tikz}
%\usepackage{minted}

\usetikzlibrary{positioning}
\usetheme{Darmstadt}

\begin{document}

\section{Structure of the compiler}
\begin{frame}{Main ideas}
	\begin{figure}
		\begin{tikzpicture}
			\node (sf) {Source file};
			\node[right =2cm of sf] (ast) {Typed AST};
			\node[right =2cm of ast] (C) {C program};
			\draw
				(sf) edge[->] node[above] {parser} (ast)
				(ast) edge[->] node[above] {compiler} (C);
		\end{tikzpicture}
		\caption{Structure of the compiler}
	\end{figure}
\end{frame}

\begin{frame}{Testing}
	\begin{block}{Passes}
		The passes can be split into:
		\begin{itemize}
			\item those checking the program validity
			\item those modifying the AST of the program
		\end{itemize}
	\end{block}
\end{frame}

\section{Typed AST}
\subsection{First attempt using GADTs}
\begin{frame}
	\begin{block}{Main idea}
		Using GADTs to represent nodes and expressions allows to ensure the
		well-typedness of a program.
	\end{block}
	\begin{figure}
		\centering
		\includegraphics[width=.75\textwidth]{imgs/gadt.png}
	\end{figure}
%type _ t_var =
%  | BVar: ident -> bool t_var
%  | IVar: ident -> int t_var
%  | RVar: ident -> real t_var
%
%type _ t_expression =
%  | EVar: 'a t_var -> 'a t_expression
%  | EMonOp: monop * 'a t_expression -> 'a t_expression
%  | EBinOp: binop * 'a t_expression * 'a t_expression -> 'a t_expression
%  | ETriOp: triop * bool t_expression * 'a t_expression * 'a t_expression -> 'a t_expression
%  | EComp:  compop * 'a t_expression * 'a t_expression -> bool t_expression
%  | EConst: 'a const -> 'a t_expression
%  | ETuple: 'a t_expression * 'b t_expression -> ('a * 'b) t_expression
%  | EApp: (('a -> 'b) t_node) * 'a t_expression -> 'b t_expression
%
%and _ t_varlist =
%  | NVar: 'a t_varlist
%  | CVar: 'a t_var * 'b t_varlist -> ('a * 'b) t_varlist
%
%and 'a t_equation = 'a t_varlist * 'a t_expression
%
%and _ t_eqlist =
%  | NEql: unit t_eqlist
%  | CEql: 'a t_equation * 'b t_eqlist -> ('a * 'b) t_eqlist
%
%and _ t_node =
%  | MakeNode:
%    ident
%    * 'i t_varlist * 'o t_varlist
%    * 'l t_varlist * 'e t_eqlist
%    -> ('i -> 'o) t_node
%
%type _ t_nodelist =
%  | NNode: unit t_nodelist
%  | CNode: ('a -> 'b) t_node * 'c t_nodelist -> (('a -> 'b) * 'c) t_nodelist
%	\end{minted}
\end{frame}
\begin{frame}
	\begin{block}{Pros of using GADTs}
		\begin{itemize}
			\item Any term of the GADT represents a well-typed program
			\item Extending the language to support more types consists of adding
				constructors to variables and constants
			\item The types are easy to read and understand
		\end{itemize}
	\end {block}

	\begin{block}{Cons of using GADTs}
		\begin{itemize}
			\item
			They cannot be dynamically generated (hence it is impossible to
			implement a parser that gives back a GADT)
			\item
			One should think about the isomorphism between
			\texttt{a $\ast$ (b $\ast$ c)} and \texttt{(a $\ast$ b) $\ast$ c}.
		\end{itemize}
	\end{block}
\end{frame}

\subsection{Second attempt: using explicit types in the variables, expressions,
\dots{} constructors}
\begin{frame}
	\begin{block}{Idea}
		Explicitly collect typing information while parsing.
	\end{block}
	\begin{figure}
		\centering
		\includegraphics[width=.6\textwidth]{imgs/explicit_types.png}
	\end{figure}
\end{frame}

\begin{frame}
	\begin{block}{Pros of using explicit types}
		\begin{itemize}
			\item Programs can be built dynamically, hence a parser can be
			written
			\item While parsing, the parser has all the required information on
			the sub-variables/nodes/expressions to check the well-typedness
		\end{itemize}
	\end{block}
	\begin{block}{Cons of these definitions}
		\begin{itemize}
			\item The typing information on terms is very redundant.
			\item The rejection of ill-typed programs depends on the correctness
			of the parser
		\end{itemize}
	\end{block}
\end{frame}

\section{Passes}
\begin{frame}{Passes}
	\begin{block}
		The passes of our compiler are functions of taking a program and either:
		\begin{itemize}
			\item returning a program if the pass succeeded
			\item returns nothing otherwise
		\end{itemize}

		We only have one language in our compiler: no intermediary language.
	\end{block}
\end{frame}

\subsection{Check}
\begin{frame}
	\begin{block}{Passes}
		The passes can be split into:
		\begin{itemize}
			\item those checking the program validity
			\item those modifying the AST of the program
		\end{itemize}
	\end{block}
\end{frame}

\begin{frame}{Implemented passes}
	\begin{block}{\texttt{pre}-propagation to leaves}
	\end{block}
	\begin{block}{Check: unique initialization for variables}
	\end{block}
	\begin{block}{Linearization of the equations}
	\end{block}
\end{frame}

\end{document}
[beamer] proto 0 2022-12-15 11:40:29 +01:00			`\documentclass{beamer}`
			`\usepackage{tikz}`
			`%\usepackage{minted}`

			`\usetikzlibrary{positioning}`
			`\usetheme{Darmstadt}`

			`\begin{document}`

			`\section{Structure of the compiler}`
			`\begin{frame}{Main ideas}`
			`\begin{figure}`
			`\begin{tikzpicture}`
			`\node (sf) {Source file};`
			`\node[right =2cm of sf] (ast) {Typed AST};`
			`\node[right =2cm of ast] (C) {C program};`
			`\draw`
			`(sf) edge[->] node[above] {parser} (ast)`
			`(ast) edge[->] node[above] {compiler} (C);`
			`\end{tikzpicture}`
			`\caption{Structure of the compiler}`
			`\end{figure}`
			`\end{frame}`

			`\begin{frame}{Testing}`
			`\begin{block}{Passes}`
			`The passes can be split into:`
			`\begin{itemize}`
			`\item those checking the program validity`
			`\item those modifying the AST of the program`
			`\end{itemize}`
			`\end{block}`
			`\end{frame}`

			`\section{Typed AST}`
			`\subsection{First attempt using GADTs}`
			`\begin{frame}`
			`\begin{block}{Main idea}`
			`Using GADTs to represent nodes and expressions allows to ensure the`
			`well-typedness of a program.`
			`\end{block}`
			`\begin{figure}`
			`\centering`
			`\includegraphics[width=.75\textwidth]{imgs/gadt.png}`
			`\end{figure}`
			`%type _ t_var =`
			`% \| BVar: ident -> bool t_var`
			`% \| IVar: ident -> int t_var`
			`% \| RVar: ident -> real t_var`
			`%`
			`%type _ t_expression =`
			`% \| EVar: 'a t_var -> 'a t_expression`
			`% \| EMonOp: monop * 'a t_expression -> 'a t_expression`
			`% \| EBinOp: binop * 'a t_expression * 'a t_expression -> 'a t_expression`
			`% \| ETriOp: triop * bool t_expression * 'a t_expression * 'a t_expression -> 'a t_expression`
			`% \| EComp: compop * 'a t_expression * 'a t_expression -> bool t_expression`
			`% \| EConst: 'a const -> 'a t_expression`
			`% \| ETuple: 'a t_expression * 'b t_expression -> ('a * 'b) t_expression`
			`% \| EApp: (('a -> 'b) t_node) * 'a t_expression -> 'b t_expression`
			`%`
			`%and _ t_varlist =`
			`% \| NVar: 'a t_varlist`
			`% \| CVar: 'a t_var * 'b t_varlist -> ('a * 'b) t_varlist`
			`%`
			`%and 'a t_equation = 'a t_varlist * 'a t_expression`
			`%`
			`%and _ t_eqlist =`
			`% \| NEql: unit t_eqlist`
			`% \| CEql: 'a t_equation * 'b t_eqlist -> ('a * 'b) t_eqlist`
			`%`
			`%and _ t_node =`
			`% \| MakeNode:`
			`% ident`
			`% * 'i t_varlist * 'o t_varlist`
			`% * 'l t_varlist * 'e t_eqlist`
			`% -> ('i -> 'o) t_node`
			`%`
			`%type _ t_nodelist =`
			`% \| NNode: unit t_nodelist`
			`% \| CNode: ('a -> 'b) t_node * 'c t_nodelist -> (('a -> 'b) * 'c) t_nodelist`
			`% \end{minted}`
			`\end{frame}`
			`\begin{frame}`
			`\begin{block}{Pros of using GADTs}`
			`\begin{itemize}`
			`\item Any term of the GADT represents a well-typed program`
			`\item Extending the language to support more types consists of adding`
			`constructors to variables and constants`
			`\item The types are easy to read and understand`
			`\end{itemize}`
			`\end {block}`

			`\begin{block}{Cons of using GADTs}`
			`\begin{itemize}`
			`\item`
			`They cannot be dynamically generated (hence it is impossible to`
			`implement a parser that gives back a GADT)`
			`\item`
			`One should think about the isomorphism between`
			`\texttt{a $\ast$ (b $\ast$ c)} and \texttt{(a $\ast$ b) $\ast$ c}.`
			`\end{itemize}`
			`\end{block}`
			`\end{frame}`

			`\subsection{Second attempt: using explicit types in the variables, expressions,`
			`\dots{} constructors}`
			`\begin{frame}`
			`\begin{block}{Idea}`
			`Explicitly collect typing information while parsing.`
			`\end{block}`
			`\begin{figure}`
			`\centering`
			`\includegraphics[width=.6\textwidth]{imgs/explicit_types.png}`
			`\end{figure}`
			`\end{frame}`

			`\begin{frame}`
			`\begin{block}{Pros of using explicit types}`
			`\begin{itemize}`
			`\item Programs can be built dynamically, hence a parser can be`
			`written`
			`\item While parsing, the parser has all the required information on`
			`the sub-variables/nodes/expressions to check the well-typedness`
			`\end{itemize}`
			`\end{block}`
			`\begin{block}{Cons of these definitions}`
			`\begin{itemize}`
			`\item The typing information on terms is very redundant.`
			`\item The rejection of ill-typed programs depends on the correctness`
			`of the parser`
			`\end{itemize}`
			`\end{block}`
			`\end{frame}`

			`\section{Passes}`
			`\begin{frame}{Passes}`
			`\begin{block}`
			`The passes of our compiler are functions of taking a program and either:`
			`\begin{itemize}`
			`\item returning a program if the pass succeeded`
			`\item returns nothing otherwise`
			`\end{itemize}`

			`We only have one language in our compiler: no intermediary language.`
			`\end{block}`
			`\end{frame}`

			`\subsection{Check}`
			`\begin{frame}`
			`\begin{block}{Passes}`
			`The passes can be split into:`
			`\begin{itemize}`
			`\item those checking the program validity`
			`\item those modifying the AST of the program`
			`\end{itemize}`
			`\end{block}`
			`\end{frame}`

			`\begin{frame}{Implemented passes}`
			`\begin{block}{\texttt{pre}-propagation to leaves}`
			`\end{block}`
			`\begin{block}{Check: unique initialization for variables}`
			`\end{block}`
			`\begin{block}{Linearization of the equations}`
			`\end{block}`
			`\end{frame}`

			`\end{document}`