--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/thys3/document/root.tex Sat Apr 30 00:50:08 2022 +0100
@@ -0,0 +1,140 @@
+\documentclass[runningheads]{lipics-v2021}
+\usepackage{times}
+\usepackage{isabelle}
+\usepackage{isabellesym}
+\usepackage{amsmath}
+\usepackage{amssymb}
+\usepackage{mathpartir}
+\usepackage{tikz}
+\usepackage{pgf}
+\usetikzlibrary{positioning}
+%\usepackage{pdfsetup}
+\usepackage{stmaryrd}
+%\usepackage{url}
+%\usepackage{color}
+%\usepackage[safe]{tipa}
+%\usepackage[sc]{mathpazo}
+%\usepackage{fontspec}
+%\setmainfont[Ligatures=TeX]{Palatino Linotype}
+
+
+
+
+\urlstyle{rm}
+\isabellestyle{it}
+\renewcommand{\isastyleminor}{\it}%
+\renewcommand{\isastyle}{\normalsize\it}%
+
+
+\def\dn{\,\stackrel{\mbox{\scriptsize def}}{=}\,}
+\renewcommand{\isasymequiv}{$\dn$}
+\renewcommand{\isasymemptyset}{$\varnothing$}
+\renewcommand{\isacharunderscore}{\mbox{$\_\!\_$}}
+\renewcommand{\isasymiota}{\makebox[0mm]{${}^{\prime}$}}
+\renewcommand{\isasymin}{\ensuremath{\,\in\,}}
+
+\addtolength{\oddsidemargin}{-1.5mm}
+\addtolength{\evensidemargin}{-1.5mm}
+\addtolength{\textwidth}{4mm}
+\addtolength{\textheight}{1.5mm}
+
+\def\lexer{\mathit{lexer}}
+\def\mkeps{\mathit{mkeps}}
+\def\inj{\mathit{inj}}
+\def\Empty{\mathit{Empty}}
+\def\Left{\mathit{Left}}
+\def\Right{\mathit{Right}}
+\def\Stars{\mathit{Stars}}
+\def\Char{\mathit{Char}}
+\def\Seq{\mathit{Seq}}
+\def\Der{\mathit{Der}}
+\def\nullable{\mathit{nullable}}
+\def\Z{\mathit{Z}}
+\def\S{\mathit{S}}
+\newcommand{\ZERO}{\mbox{\bf 0}}
+\newcommand{\ONE}{\mbox{\bf 1}}
+\def\rs{\mathit{rs}}
+
+\def\Brz{Brzozowski}
+\def\der{\backslash}
+\newtheorem{falsehood}{Falsehood}
+\newtheorem{conject}{Conjecture}
+
+\bibliographystyle{plainurl}
+
+\title{{POSIX} {L}exing with {B}itcoded {D}erivatives}
+\titlerunning{POSIX Lexing with Bitcoded Derivatives}
+\author{Chengsong Tan}{King's College London}{chengsong.tan@kcl.ac.uk}{}{}
+\author{Christian Urban}{King's College London}{christian.urban@kcl.ac.uk}{}{}
+\authorrunning{C.~Tan and C.~Urban}
+\keywords{POSIX matching and lexing, derivatives of regular expressions, Isabelle/HOL}
+\category{}
+\ccsdesc[100]{Design and analysis of algorithms}
+\ccsdesc[100]{Formal languages and automata theory}
+\Copyright{\mbox{}}
+\renewcommand{\DOIPrefix}{}
+\nolinenumbers
+
+
+\begin{document}
+\maketitle
+
+\begin{abstract}
+ Sulzmann and Lu describe a lexing algorithm that calculates
+ Brzozowski derivatives using bitcodes annotated to regular
+ expressions. Their algorithm generates POSIX values which encode
+ the information of \emph{how} a regular expression matches a
+ string---that is, which part of the string is matched by which part
+ of the regular expression. This information is needed in the
+ context of lexing in order to extract and to classify tokens.
+ The purpose of the bitcodes is to generate POSIX values incrementally while
+ derivatives are calculated. They also help with designing
+ an ``aggressive'' simplification function that keeps the size of
+ derivatives finitely bounded. Without simplification the size of some derivatives can grow
+ arbitrarily big, resulting in an extremely slow lexing algorithm. In this
+ paper we describe a variant of Sulzmann and Lu's algorithm: Our
+ variant is a recursive functional program, whereas Sulzmann
+ and Lu's version involves a fixpoint construction. We \textit{(i)}
+ prove in Isabelle/HOL that our algorithm is correct and generates
+ unique POSIX values; we also \textit{(ii)} establish finite
+ bounds for the size of the derivatives.
+
+ %The size can be seen as a
+ %proxy measure for the efficiency of the lexing algorithm: because of
+ %the polynomial bound our algorithm does not suffer from
+ %the exponential blowup in earlier works.
+
+ % Brzozowski introduced the notion of derivatives for regular
+ % expressions. They can be used for a very simple regular expression
+ % matching algorithm. Sulzmann and Lu cleverly extended this
+ % algorithm in order to deal with POSIX matching, which is the
+ % underlying disambiguation strategy for regular expressions needed
+ % in lexers. Their algorithm generates POSIX values which encode
+ % the information of \emph{how} a regular expression matches a
+ % string---that is, which part of the string is matched by which
+ % part of the regular expression. In this paper we give our
+ % inductive definition of what a POSIX value is and show $(i)$ that
+ % such a value is unique (for given regular expression and string
+ % being matched) and $(ii)$ that Sulzmann and Lu's algorithm always
+ % generates such a value (provided that the regular expression
+ % matches the string). We show that $(iii)$ our inductive definition
+ % of a POSIX value is equivalent to an alternative definition by
+ % Okui and Suzuki which identifies POSIX values as least elements
+ % according to an ordering of values. We also prove the correctness
+ % of Sulzmann's bitcoded version of the POSIX matching algorithm and
+ % extend the results to additional constructors for regular
+ % expressions. \smallskip
+\end{abstract}
+
+
+
+\input{session}
+
+
+
+\end{document}
+
+%%% Local Variables:
+%%% mode: latex
+%%% TeX-master: t
+%%% End: