| author | Christian Urban <urbanc@in.tum.de> |
| Fri, 30 Nov 2018 08:56:22 +0000 | |
| changeset 225 | cb11ae7170fe |
| parent 221 | d061f3a94fa7 |
| child 229 | cfcaf4a5e5b4 |
| permissions | -rw-r--r-- |
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\documentclass{article}
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\usepackage{../style}
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\usepackage{../langs}
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\usepackage{disclaimer}
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\usepackage{tikz}
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\usepackage{pgf}
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\usepackage{pgfplots}
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\usepackage{stackengine}
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%% \usepackage{accents}
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\newcommand\barbelow[1]{\stackunder[1.2pt]{#1}{\raisebox{-4mm}{\boldmath$\uparrow$}}}
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\begin{filecontents}{re-python2.data}
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22 0.485 |
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23 0.878 |
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24 1.71 |
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\end{filecontents}
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\begin{filecontents}{re-js.data}
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\begin{document}
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% BF IDE |
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% https://www.microsoft.com/en-us/p/brainf-ck/9nblgggzhvq5 |
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\section*{Coursework 9 (Scala)}
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This coursework is worth 10\%. It is about a regular expression |
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matcher and the shunting yard algorithm by Dijkstra. The first part is |
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due on 6 December at 11pm; the second, more advanced part, is due on |
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21 December at 11pm. In the first part, you are asked to implement a |
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regular expression matcher based on derivatives of regular |
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expressions. The reason is that regular expression matching in |
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languages like Java, JavaScipt and Python can sometimes be extremely |
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slow. The advanced part is about the shunting yard algorithm that |
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transforms the usual infix notation of arithmetic expressions into the |
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postfix notation, which is for example used in compilers.\bigskip |
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\IMPORTANT{}
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\noindent |
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Also note that the running time of each part will be restricted to a |
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maximum of 30 seconds on my laptop. |
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\DISCLAIMER{}
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\subsection*{Part 1 (6 Marks, Regular Expression Matcher)}
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The task is to implement a regular expression matcher that is based on |
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derivatives of regular expressions. Most of the functions are defined by |
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recursion over regular expressions and can be elegantly implemented |
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using Scala's pattern-matching. The implementation should deal with the |
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following regular expressions, which have been predefined in the file |
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\texttt{re.scala}:
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\begin{center}
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\begin{tabular}{lcll}
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$r$ & $::=$ & $\ZERO$ & cannot match anything\\ |
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& $|$ & $\ONE$ & can only match the empty string\\ |
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& $|$ & $c$ & can match a single character (in this case $c$)\\ |
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& $|$ & $r_1 + r_2$ & can match a string either with $r_1$ or with $r_2$\\ |
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& $|$ & $r_1\cdot r_2$ & can match the first part of a string with $r_1$ and\\ |
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& & & then the second part with $r_2$\\ |
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& $|$ & $r^*$ & can match a string with zero or more copies of $r$\\ |
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\end{tabular}
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\end{center}
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\noindent |
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Why? Knowing how to match regular expressions and strings will let you |
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solve a lot of problems that vex other humans. Regular expressions are |
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one of the fastest and simplest ways to match patterns in text, and |
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are endlessly useful for searching, editing and analysing data in all |
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sorts of places (for example analysing network traffic in order to |
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detect security breaches). However, you need to be fast, otherwise you |
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will stumble over problems such as recently reported at |
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{\small
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\begin{itemize}
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\item[$\bullet$] \url{http://stackstatus.net/post/147710624694/outage-postmortem-july-20-2016}
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\item[$\bullet$] \url{https://vimeo.com/112065252}
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\item[$\bullet$] \url{http://davidvgalbraith.com/how-i-fixed-atom/}
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\end{itemize}}
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\subsubsection*{Tasks (file re.scala)}
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The file \texttt{re.scala} has already a definition for regular
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expressions and also defines some handy shorthand notation for |
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regular expressions. The notation in this document matches up |
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with the code in the file as follows: |
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\begin{center}
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\begin{tabular}{rcl@{\hspace{10mm}}l}
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& & code: & shorthand:\smallskip \\ |
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$\ZERO$ & $\mapsto$ & \texttt{ZERO}\\
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$\ONE$ & $\mapsto$ & \texttt{ONE}\\
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$c$ & $\mapsto$ & \texttt{CHAR(c)}\\
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$r_1 + r_2$ & $\mapsto$ & \texttt{ALT(r1, r2)} & \texttt{r1 | r2}\\
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$r_1 \cdot r_2$ & $\mapsto$ & \texttt{SEQ(r1, r2)} & \texttt{r1 $\sim$ r2}\\
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$r^*$ & $\mapsto$ & \texttt{STAR(r)} & \texttt{r.\%}
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\end{tabular}
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\end{center}
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\begin{itemize}
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\item[(1)] Implement a function, called \textit{nullable}, by
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recursion over regular expressions. This function tests whether a |
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regular expression can match the empty string. This means given a |
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regular expression it either returns true or false. The function |
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\textit{nullable}
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is defined as follows: |
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\begin{center}
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\begin{tabular}{lcl}
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$\textit{nullable}(\ZERO)$ & $\dn$ & $\textit{false}$\\
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$\textit{nullable}(\ONE)$ & $\dn$ & $\textit{true}$\\
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$\textit{nullable}(c)$ & $\dn$ & $\textit{false}$\\
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$\textit{nullable}(r_1 + r_2)$ & $\dn$ & $\textit{nullable}(r_1) \vee \textit{nullable}(r_2)$\\
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$\textit{nullable}(r_1 \cdot r_2)$ & $\dn$ & $\textit{nullable}(r_1) \wedge \textit{nullable}(r_2)$\\
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$\textit{nullable}(r^*)$ & $\dn$ & $\textit{true}$\\
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\end{tabular}
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\end{center}~\hfill[1 Mark]
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\item[(2)] Implement a function, called \textit{der}, by recursion over
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regular expressions. It takes a character and a regular expression |
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as arguments and calculates the derivative regular expression according |
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to the rules: |
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\begin{center}
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\begin{tabular}{lcl}
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$\textit{der}\;c\;(\ZERO)$ & $\dn$ & $\ZERO$\\
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$\textit{der}\;c\;(\ONE)$ & $\dn$ & $\ZERO$\\
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$\textit{der}\;c\;(d)$ & $\dn$ & $\textit{if}\; c = d\;\textit{then} \;\ONE \; \textit{else} \;\ZERO$\\
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$\textit{der}\;c\;(r_1 + r_2)$ & $\dn$ & $(\textit{der}\;c\;r_1) + (\textit{der}\;c\;r_2)$\\
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$\textit{der}\;c\;(r_1 \cdot r_2)$ & $\dn$ & $\textit{if}\;\textit{nullable}(r_1)$\\
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& & $\textit{then}\;((\textit{der}\;c\;r_1)\cdot r_2) + (\textit{der}\;c\;r_2)$\\
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& & $\textit{else}\;(\textit{der}\;c\;r_1)\cdot r_2$\\
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$\textit{der}\;c\;(r^*)$ & $\dn$ & $(\textit{der}\;c\;r)\cdot (r^*)$\\
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\end{tabular}
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\end{center}
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For example given the regular expression $r = (a \cdot b) \cdot c$, the derivatives |
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w.r.t.~the characters $a$, $b$ and $c$ are |
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\begin{center}
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\begin{tabular}{lcll}
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$\textit{der}\;a\;r$ & $=$ & $(\ONE \cdot b)\cdot c$ & \quad($= r'$)\\
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$\textit{der}\;b\;r$ & $=$ & $(\ZERO \cdot b)\cdot c$\\
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$\textit{der}\;c\;r$ & $=$ & $(\ZERO \cdot b)\cdot c$
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\end{tabular}
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\end{center}
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Let $r'$ stand for the first derivative, then taking the derivatives of $r'$ |
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w.r.t.~the characters $a$, $b$ and $c$ gives |
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\begin{center}
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\begin{tabular}{lcll}
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$\textit{der}\;a\;r'$ & $=$ & $((\ZERO \cdot b) + \ZERO)\cdot c$ \\
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$\textit{der}\;b\;r'$ & $=$ & $((\ZERO \cdot b) + \ONE)\cdot c$ & \quad($= r''$)\\
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$\textit{der}\;c\;r'$ & $=$ & $((\ZERO \cdot b) + \ZERO)\cdot c$
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\end{tabular}
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\end{center}
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One more example: Let $r''$ stand for the second derivative above, |
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then taking the derivatives of $r''$ w.r.t.~the characters $a$, $b$ |
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and $c$ gives |
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\begin{center}
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\begin{tabular}{lcll}
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$\textit{der}\;a\;r''$ & $=$ & $((\ZERO \cdot b) + \ZERO) \cdot c + \ZERO$ \\
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$\textit{der}\;b\;r''$ & $=$ & $((\ZERO \cdot b) + \ZERO) \cdot c + \ZERO$\\
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$\textit{der}\;c\;r''$ & $=$ & $((\ZERO \cdot b) + \ZERO) \cdot c + \ONE$ &
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(is $\textit{nullable}$)
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\end{tabular}
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\end{center}
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Note, the last derivative can match the empty string, that is it is \textit{nullable}.\\
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\mbox{}\hfill\mbox{[1 Mark]}
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\item[(3)] Implement the function \textit{simp}, which recursively
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traverses a regular expression from the inside to the outside, and |
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on the way simplifies every regular expression on the left (see |
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below) to the regular expression on the right, except it does not |
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simplify inside ${}^*$-regular expressions.
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\begin{center}
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\begin{tabular}{l@{\hspace{4mm}}c@{\hspace{4mm}}ll}
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$r \cdot \ZERO$ & $\mapsto$ & $\ZERO$\\ |
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$\ZERO \cdot r$ & $\mapsto$ & $\ZERO$\\ |
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$r \cdot \ONE$ & $\mapsto$ & $r$\\ |
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$\ONE \cdot r$ & $\mapsto$ & $r$\\ |
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$r + \ZERO$ & $\mapsto$ & $r$\\ |
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$\ZERO + r$ & $\mapsto$ & $r$\\ |
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$r + r$ & $\mapsto$ & $r$\\ |
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\end{tabular}
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\end{center}
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For example the regular expression |
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\[(r_1 + \ZERO) \cdot \ONE + ((\ONE + r_2) + r_3) \cdot (r_4 \cdot \ZERO)\] |
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simplifies to just $r_1$. \textbf{Hint:} Regular expressions can be
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seen as trees and there are several methods for traversing |
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trees. One of them corresponds to the inside-out traversal, which is |
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sometimes also called post-order traversal'' you traverse inside the |
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tree and on the way up, you apply simplification rules. |
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Furthermore, |
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remember numerical expressions from school times: there you had expressions |
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like $u + \ldots + (1 \cdot x) - \ldots (z + (y \cdot 0)) \ldots$ |
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and simplification rules that looked very similar to rules |
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above. You would simplify such numerical expressions by replacing |
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for example the $y \cdot 0$ by $0$, or $1\cdot x$ by $x$, and then |
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look whether more rules are applicable. If you organise the |
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simplification in an inside-out fashion, it is always clear which |
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rule should be applied next.\hfill[1 Mark] |
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\item[(4)] Implement two functions: The first, called \textit{ders},
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takes a list of characters and a regular expression as arguments, and |
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builds the derivative w.r.t.~the list as follows: |
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\begin{center}
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\begin{tabular}{lcl}
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$\textit{ders}\;(Nil)\;r$ & $\dn$ & $r$\\
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$\textit{ders}\;(c::cs)\;r$ & $\dn$ &
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$\textit{ders}\;cs\;(\textit{simp}(\textit{der}\;c\;r))$\\
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\end{tabular}
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\end{center}
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Note that this function is different from \textit{der}, which only
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takes a single character. |
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The second function, called \textit{matcher}, takes a string and a
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regular expression as arguments. It builds first the derivatives |
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according to \textit{ders} and after that tests whether the resulting
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derivative regular expression can match the empty string (using |
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\textit{nullable}). For example the \textit{matcher} will produce
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true for the regular expression $(a\cdot b)\cdot c$ and the string |
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$abc$, but false if you give it the string $ab$. \hfill[1 Mark] |
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\item[(5)] Implement a function, called \textit{size}, by recursion
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over regular expressions. If a regular expression is seen as a tree, |
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then \textit{size} should return the number of nodes in such a
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tree. Therefore this function is defined as follows: |
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\begin{center}
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\begin{tabular}{lcl}
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$\textit{size}(\ZERO)$ & $\dn$ & $1$\\
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$\textit{size}(\ONE)$ & $\dn$ & $1$\\
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$\textit{size}(c)$ & $\dn$ & $1$\\
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$\textit{size}(r_1 + r_2)$ & $\dn$ & $1 + \textit{size}(r_1) + \textit{size}(r_2)$\\
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$\textit{size}(r_1 \cdot r_2)$ & $\dn$ & $1 + \textit{size}(r_1) + \textit{size}(r_2)$\\
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$\textit{size}(r^*)$ & $\dn$ & $1 + \textit{size}(r)$\\
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\end{tabular}
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\end{center}
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You can use \textit{size} in order to test how much the `evil' regular
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expression $(a^*)^* \cdot b$ grows when taking successive derivatives |
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according the letter $a$ without simplification and then compare it to |
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taking the derivative, but simplify the result. The sizes |
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are given in \texttt{re.scala}. \hfill[1 Mark]
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\item[(6)] You do not have to implement anything specific under this |
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task. The purpose is that you will be marked for some ``power'' |
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test cases. For example can your matcher decide withing 30 seconds |
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whether the regular expression $(a^*)^*\cdot b$ matches strings of the |
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form $aaa\ldots{}aaaa$, for say 1 Million $a$'s. And does simplification
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simplify the regular expression |
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\[ |
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\texttt{SEQ(SEQ(SEQ(..., ONE | ONE) , ONE | ONE), ONE | ONE)}
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\] |
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\noindent correctly to just \texttt{ONE}, where \texttt{SEQ} is nested
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50 or more times.\\ |
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\mbox{}\hfill[1 Mark]
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Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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changeset
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\end{itemize}
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parents:
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\subsection*{Background}
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Although easily implementable in Scala, the idea behind the derivative |
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function might not so easy to be seen. To understand its purpose |
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better, assume a regular expression $r$ can match strings of the form |
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$c\!::\!cs$ (that means strings which start with a character $c$ and have |
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some rest, or tail, $cs$). If you take the derivative of $r$ with |
|
354 |
respect to the character $c$, then you obtain a regular expression |
|
355 |
that can match all the strings $cs$. In other words, the regular |
|
356 |
expression $\textit{der}\;c\;r$ can match the same strings $c\!::\!cs$
|
|
357 |
that can be matched by $r$, except that the $c$ is chopped off. |
|
358 |
||
359 |
Assume now $r$ can match the string $abc$. If you take the derivative |
|
360 |
according to $a$ then you obtain a regular expression that can match |
|
361 |
$bc$ (it is $abc$ where the $a$ has been chopped off). If you now |
|
362 |
build the derivative $\textit{der}\;b\;(\textit{der}\;a\;r)$ you
|
|
363 |
obtain a regular expression that can match the string $c$ (it is $bc$ |
|
364 |
where $b$ is chopped off). If you finally build the derivative of this |
|
365 |
according $c$, that is |
|
366 |
$\textit{der}\;c\;(\textit{der}\;b\;(\textit{der}\;a\;r))$, you obtain
|
|
367 |
a regular expression that can match the empty string. You can test |
|
368 |
whether this is indeed the case using the function nullable, which is |
|
369 |
what your matcher is doing. |
|
370 |
||
371 |
The purpose of the $\textit{simp}$ function is to keep the regular
|
|
372 |
expressions small. Normally the derivative function makes the regular |
|
| 221 | 373 |
expression bigger (see the SEQ case and the example in (2)) and the |
| 218 | 374 |
algorithm would be slower and slower over time. The $\textit{simp}$
|
375 |
function counters this increase in size and the result is that the |
|
376 |
algorithm is fast throughout. By the way, this algorithm is by Janusz |
|
377 |
Brzozowski who came up with the idea of derivatives in 1964 in his PhD |
|
378 |
thesis. |
|
379 |
||
380 |
\begin{center}\small
|
|
381 |
\url{https://en.wikipedia.org/wiki/Janusz_Brzozowski_(computer_scientist)}
|
|
382 |
\end{center}
|
|
383 |
||
|
105
0f9f774c7697
updated
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
100
diff
changeset
|
384 |
|
| 218 | 385 |
If you want to see how badly the regular expression matchers do in |
| 221 | 386 |
Java\footnote{Version 8 and below; Version 9 and above does not seem to be as
|
387 |
catastrophic, but still much worse than the regular expression |
|
388 |
matcher based on derivatives.}, JavaScript and in Python with the |
|
389 |
`evil' regular expression $(a^*)^*\cdot b$, then have a look at the |
|
390 |
graphs below (you can try it out for yourself: have a look at the file |
|
391 |
\texttt{catastrophic9.java}, \texttt{catastrophic.js} and
|
|
392 |
\texttt{catastrophic.py} on KEATS). Compare this with the matcher you
|
|
393 |
have implemented. How long can the string of $a$'s be in your matcher |
|
394 |
and still stay within the 30 seconds time limit? |
|
| 78 | 395 |
|
| 218 | 396 |
\begin{center}
|
397 |
\begin{tabular}{@{}cc@{}}
|
|
398 |
\multicolumn{2}{c}{Graph: $(a^*)^*\cdot b$ and strings
|
|
399 |
$\underbrace{a\ldots a}_{n}$}\bigskip\\
|
|
400 |
||
401 |
\begin{tikzpicture}
|
|
402 |
\begin{axis}[
|
|
403 |
xlabel={$n$},
|
|
404 |
x label style={at={(1.05,0.0)}},
|
|
405 |
ylabel={time in secs},
|
|
406 |
y label style={at={(0.06,0.5)}},
|
|
407 |
enlargelimits=false, |
|
408 |
xtick={0,5,...,30},
|
|
409 |
xmax=33, |
|
410 |
ymax=45, |
|
411 |
ytick={0,5,...,40},
|
|
412 |
scaled ticks=false, |
|
413 |
axis lines=left, |
|
414 |
width=6cm, |
|
415 |
height=5.5cm, |
|
| 221 | 416 |
legend entries={Python, Java 8, JavaScript},
|
| 218 | 417 |
legend pos=north west] |
418 |
\addplot[blue,mark=*, mark options={fill=white}] table {re-python2.data};
|
|
419 |
\addplot[cyan,mark=*, mark options={fill=white}] table {re-java.data};
|
|
| 221 | 420 |
\addplot[red,mark=*, mark options={fill=white}] table {re-js.data};
|
| 218 | 421 |
\end{axis}
|
422 |
\end{tikzpicture}
|
|
423 |
& |
|
424 |
\begin{tikzpicture}
|
|
425 |
\begin{axis}[
|
|
426 |
xlabel={$n$},
|
|
427 |
x label style={at={(1.05,0.0)}},
|
|
428 |
ylabel={time in secs},
|
|
429 |
y label style={at={(0.06,0.5)}},
|
|
430 |
%enlargelimits=false, |
|
431 |
%xtick={0,5000,...,30000},
|
|
432 |
xmax=65000, |
|
433 |
ymax=45, |
|
434 |
ytick={0,5,...,40},
|
|
435 |
scaled ticks=false, |
|
436 |
axis lines=left, |
|
437 |
width=6cm, |
|
438 |
height=5.5cm, |
|
439 |
legend entries={Java 9},
|
|
440 |
legend pos=north west] |
|
441 |
\addplot[cyan,mark=*, mark options={fill=white}] table {re-java9.data};
|
|
442 |
\end{axis}
|
|
443 |
\end{tikzpicture}
|
|
444 |
\end{tabular}
|
|
445 |
\end{center}
|
|
446 |
\newpage |
|
447 |
||
448 |
\subsection*{Part 2 (4 Marks)}
|
|
449 |
||
450 |
Coming from Java or C++, you might think Scala is a quite esoteric |
|
451 |
programming language. But remember, some serious companies have built |
|
452 |
their business on |
|
453 |
Scala.\footnote{\url{https://en.wikipedia.org/wiki/Scala_(programming_language)\#Companies}}
|
|
454 |
And there are far, far more esoteric languages out there. One is |
|
455 |
called \emph{brainf***}. You are asked in this part to implement an
|
|
456 |
interpreter for this language. |
|
457 |
||
458 |
Urban M\"uller developed brainf*** in 1993. A close relative of this |
|
459 |
language was already introduced in 1964 by Corado B\"ohm, an Italian |
|
460 |
computer pioneer, who unfortunately died a few months ago. The main |
|
461 |
feature of brainf*** is its minimalistic set of instructions---just 8 |
|
462 |
instructions in total and all of which are single characters. Despite |
|
463 |
the minimalism, this language has been shown to be Turing |
|
464 |
complete\ldots{}if this doesn't ring any bell with you: it roughly
|
|
465 |
means that every algorithm we know can, in principle, be implemented in |
|
466 |
brainf***. It just takes a lot of determination and quite a lot of |
|
467 |
memory resources. Some relatively sophisticated sample programs in |
|
468 |
brainf*** are given in the file \texttt{bf.scala}.\bigskip
|
|
469 |
||
470 |
\noindent |
|
471 |
As mentioned above, brainf*** has 8 single-character commands, namely |
|
472 |
\texttt{'>'}, \texttt{'<'}, \texttt{'+'}, \texttt{'-'}, \texttt{'.'},
|
|
473 |
\texttt{','}, \texttt{'['} and \texttt{']'}. Every other character is
|
|
474 |
considered a comment. Brainf*** operates on memory cells containing |
|
475 |
integers. For this it uses a single memory pointer that points at each |
|
476 |
stage to one memory cell. This pointer can be moved forward by one |
|
477 |
memory cell by using the command \texttt{'>'}, and backward by using
|
|
478 |
\texttt{'<'}. The commands \texttt{'+'} and \texttt{'-'} increase,
|
|
479 |
respectively decrease, by 1 the content of the memory cell to which |
|
480 |
the memory pointer currently points to. The commands for input/output |
|
481 |
are \texttt{','} and \texttt{'.'}. Output works by reading the content
|
|
482 |
of the memory cell to which the memory pointer points to and printing |
|
483 |
it out as an ASCII character. Input works the other way, taking some |
|
484 |
user input and storing it in the cell to which the memory pointer |
|
485 |
points to. The commands \texttt{'['} and \texttt{']'} are looping
|
|
486 |
constructs. Everything in between \texttt{'['} and \texttt{']'} is
|
|
487 |
repeated until a counter (memory cell) reaches zero. A typical |
|
488 |
program in brainf*** looks as follows: |
|
489 |
||
490 |
\begin{center}
|
|
491 |
\begin{verbatim}
|
|
492 |
++++++++[>++++[>++>+++>+++>+<<<<-]>+>+>->>+[<]<-]>>.>---.+++++++ |
|
493 |
..+++.>>.<-.<.+++.------.--------.>>+.>++. |
|
494 |
\end{verbatim}
|
|
495 |
\end{center}
|
|
496 |
||
497 |
\noindent |
|
498 |
This one prints out Hello World\ldots{}obviously.
|
|
499 |
||
500 |
\subsubsection*{Tasks (file bf.scala)}
|
|
| 109 | 501 |
|
502 |
\begin{itemize}
|
|
| 218 | 503 |
\item[(2a)] Brainf*** memory is represented by a \texttt{Map} from
|
504 |
integers to integers. The empty memory is represented by |
|
505 |
\texttt{Map()}, that is nothing is stored in the
|
|
506 |
memory. \texttt{Map(0 -> 1, 2 -> 3)} clearly stores \texttt{1} at
|
|
507 |
memory location \texttt{0}; at \texttt{2} it stores \texttt{3}. The
|
|
508 |
convention is that if we query the memory at a location that is |
|
509 |
\emph{not} defined in the \texttt{Map}, we return \texttt{0}. Write
|
|
510 |
a function, \texttt{sread}, that takes a memory (a \texttt{Map}) and
|
|
511 |
a memory pointer (an \texttt{Int}) as argument, and safely reads the
|
|
512 |
corresponding memory location. If the \texttt{Map} is not defined at
|
|
513 |
the memory pointer, \texttt{sread} returns \texttt{0}.
|
|
514 |
||
515 |
Write another function \texttt{write}, which takes a memory, a
|
|
516 |
memory pointer and an integer value as argument and updates the |
|
517 |
\texttt{Map} with the value at the given memory location. As usual
|
|
518 |
the \texttt{Map} is not updated `in-place' but a new map is created
|
|
519 |
with the same data, except the value is stored at the given memory |
|
520 |
pointer.\hfill[1 Mark] |
|
521 |
||
522 |
\item[(2b)] Write two functions, \texttt{jumpRight} and
|
|
523 |
\texttt{jumpLeft} that are needed to implement the loop constructs
|
|
524 |
of brainf***. They take a program (a \texttt{String}) and a program
|
|
525 |
counter (an \texttt{Int}) as argument and move right (respectively
|
|
526 |
left) in the string in order to find the \textbf{matching}
|
|
527 |
opening/closing bracket. For example, given the following program |
|
528 |
with the program counter indicated by an arrow: |
|
529 |
||
530 |
\begin{center}
|
|
531 |
\texttt{--[\barbelow{.}.+>--],>,++}
|
|
532 |
\end{center}
|
|
533 |
||
534 |
then the matching closing bracket is in 9th position (counting from 0) and |
|
535 |
\texttt{jumpRight} is supposed to return the position just after this
|
|
| 109 | 536 |
|
| 218 | 537 |
\begin{center}
|
538 |
\texttt{--[..+>--]\barbelow{,}>,++}
|
|
539 |
\end{center}
|
|
540 |
||
541 |
meaning it jumps to after the loop. Similarly, if you are in 8th position |
|
542 |
then \texttt{jumpLeft} is supposed to jump to just after the opening
|
|
543 |
bracket (that is jumping to the beginning of the loop): |
|
| 109 | 544 |
|
| 218 | 545 |
\begin{center}
|
546 |
\texttt{--[..+>-\barbelow{-}],>,++}
|
|
547 |
\qquad$\stackrel{\texttt{jumpLeft}}{\longrightarrow}$\qquad
|
|
548 |
\texttt{--[\barbelow{.}.+>--],>,++}
|
|
549 |
\end{center}
|
|
550 |
||
551 |
Unfortunately we have to take into account that there might be |
|
552 |
other opening and closing brackets on the `way' to find the |
|
553 |
matching bracket. For example in the brainf*** program |
|
554 |
||
555 |
\begin{center}
|
|
556 |
\texttt{--[\barbelow{.}.[+>]--],>,++}
|
|
557 |
\end{center}
|
|
| 109 | 558 |
|
| 218 | 559 |
we do not want to return the index for the \texttt{'-'} in the 9th
|
560 |
position, but the program counter for \texttt{','} in 12th
|
|
561 |
position. The easiest to find out whether a bracket is matched is by |
|
562 |
using levels (which are the third argument in \texttt{jumpLeft} and
|
|
563 |
\texttt{jumpLeft}). In case of \texttt{jumpRight} you increase the
|
|
564 |
level by one whenever you find an opening bracket and decrease by |
|
565 |
one for a closing bracket. Then in \texttt{jumpRight} you are looking
|
|
566 |
for the closing bracket on level \texttt{0}. For \texttt{jumpLeft} you
|
|
567 |
do the opposite. In this way you can find \textbf{matching} brackets
|
|
568 |
in strings such as |
|
569 |
||
570 |
\begin{center}
|
|
571 |
\texttt{--[\barbelow{.}.[[-]+>[.]]--],>,++}
|
|
572 |
\end{center}
|
|
| 109 | 573 |
|
| 218 | 574 |
for which \texttt{jumpRight} should produce the position:
|
575 |
||
576 |
\begin{center}
|
|
577 |
\texttt{--[..[[-]+>[.]]--]\barbelow{,}>,++}
|
|
578 |
\end{center}
|
|
579 |
||
580 |
It is also possible that the position returned by \texttt{jumpRight} or
|
|
581 |
\texttt{jumpLeft} is outside the string in cases where there are
|
|
582 |
no matching brackets. For example |
|
583 |
||
584 |
\begin{center}
|
|
585 |
\texttt{--[\barbelow{.}.[[-]+>[.]]--,>,++}
|
|
586 |
\qquad$\stackrel{\texttt{jumpRight}}{\longrightarrow}$\qquad
|
|
587 |
\texttt{--[..[[-]+>[.]]-->,++\barbelow{\;\phantom{+}}}
|
|
588 |
\end{center}
|
|
589 |
\hfill[1 Mark] |
|
| 109 | 590 |
|
591 |
||
| 218 | 592 |
\item[(2c)] Write a recursive function \texttt{run} that executes a
|
593 |
brainf*** program. It takes a program, a program counter, a memory |
|
594 |
pointer and a memory as arguments. If the program counter is outside |
|
595 |
the program string, the execution stops and \texttt{run} returns the
|
|
596 |
memory. If the program counter is inside the string, it reads the |
|
597 |
corresponding character and updates the program counter \texttt{pc},
|
|
598 |
memory pointer \texttt{mp} and memory \texttt{mem} according to the
|
|
599 |
rules shown in Figure~\ref{comms}. It then calls recursively
|
|
600 |
\texttt{run} with the updated data.
|
|
601 |
||
602 |
Write another function \texttt{start} that calls \texttt{run} with a
|
|
603 |
given brainfu** program and memory, and the program counter and memory pointer |
|
604 |
set to~$0$. Like \texttt{run} it returns the memory after the execution
|
|
605 |
of the program finishes. You can test your brainf**k interpreter with the |
|
606 |
Sierpinski triangle or the Hello world programs or have a look at |
|
| 109 | 607 |
|
| 218 | 608 |
\begin{center}
|
609 |
\url{https://esolangs.org/wiki/Brainfuck}
|
|
610 |
\end{center}\hfill[2 Marks]
|
|
| 109 | 611 |
|
| 218 | 612 |
\begin{figure}[p]
|
613 |
\begin{center}
|
|
614 |
\begin{tabular}{|@{}p{0.8cm}|l|}
|
|
615 |
\hline |
|
616 |
\hfill\texttt{'>'} & \begin{tabular}[t]{@{}l@{\hspace{2mm}}l@{}}
|
|
617 |
$\bullet$ & $\texttt{pc} + 1$\\
|
|
618 |
$\bullet$ & $\texttt{mp} + 1$\\
|
|
619 |
$\bullet$ & \texttt{mem} unchanged
|
|
620 |
\end{tabular}\\\hline
|
|
621 |
\hfill\texttt{'<'} & \begin{tabular}[t]{@{}l@{\hspace{2mm}}l@{}}
|
|
622 |
$\bullet$ & $\texttt{pc} + 1$\\
|
|
623 |
$\bullet$ & $\texttt{mp} - 1$\\
|
|
624 |
$\bullet$ & \texttt{mem} unchanged
|
|
625 |
\end{tabular}\\\hline
|
|
626 |
\hfill\texttt{'+'} & \begin{tabular}[t]{@{}l@{\hspace{2mm}}l@{}}
|
|
627 |
$\bullet$ & $\texttt{pc} + 1$\\
|
|
628 |
$\bullet$ & $\texttt{mp}$ unchanged\\
|
|
629 |
$\bullet$ & \texttt{mem} updated with \texttt{mp -> mem(mp) + 1}\\
|
|
630 |
\end{tabular}\\\hline
|
|
631 |
\hfill\texttt{'-'} & \begin{tabular}[t]{@{}l@{\hspace{2mm}}l@{}}
|
|
632 |
$\bullet$ & $\texttt{pc} + 1$\\
|
|
633 |
$\bullet$ & $\texttt{mp}$ unchanged\\
|
|
634 |
$\bullet$ & \texttt{mem} updated with \texttt{mp -> mem(mp) - 1}\\
|
|
635 |
\end{tabular}\\\hline
|
|
636 |
\hfill\texttt{'.'} & \begin{tabular}[t]{@{}l@{\hspace{2mm}}l@{}}
|
|
637 |
$\bullet$ & $\texttt{pc} + 1$\\
|
|
638 |
$\bullet$ & $\texttt{mp}$ and \texttt{mem} unchanged\\
|
|
639 |
$\bullet$ & print out \,\texttt{mem(mp)} as a character\\
|
|
640 |
\end{tabular}\\\hline
|
|
641 |
\hfill\texttt{','} & \begin{tabular}[t]{@{}l@{\hspace{2mm}}l@{}}
|
|
642 |
$\bullet$ & $\texttt{pc} + 1$\\
|
|
643 |
$\bullet$ & $\texttt{mp}$ unchanged\\
|
|
644 |
$\bullet$ & \texttt{mem} updated with \texttt{mp -> \textrm{input}}\\
|
|
645 |
\multicolumn{2}{@{}l}{the input is given by \texttt{Console.in.read().toByte}}
|
|
646 |
\end{tabular}\\\hline
|
|
647 |
\hfill\texttt{'['} & \begin{tabular}[t]{@{}l@{\hspace{2mm}}l@{}}
|
|
648 |
\multicolumn{2}{@{}l}{if \texttt{mem(mp) == 0} then}\\
|
|
649 |
$\bullet$ & $\texttt{pc = jumpRight(prog, pc + 1, 0)}$\\
|
|
650 |
$\bullet$ & $\texttt{mp}$ and \texttt{mem} unchanged\medskip\\
|
|
651 |
\multicolumn{2}{@{}l}{otherwise if \texttt{mem(mp) != 0} then}\\
|
|
652 |
$\bullet$ & $\texttt{pc} + 1$\\
|
|
653 |
$\bullet$ & $\texttt{mp}$ and \texttt{mem} unchanged\\
|
|
654 |
\end{tabular}
|
|
655 |
\\\hline |
|
656 |
\hfill\texttt{']'} & \begin{tabular}[t]{@{}l@{\hspace{2mm}}l@{}}
|
|
657 |
\multicolumn{2}{@{}l}{if \texttt{mem(mp) != 0} then}\\
|
|
658 |
$\bullet$ & $\texttt{pc = jumpLeft(prog, pc - 1, 0)}$\\
|
|
659 |
$\bullet$ & $\texttt{mp}$ and \texttt{mem} unchanged\medskip\\
|
|
660 |
\multicolumn{2}{@{}l}{otherwise if \texttt{mem(mp) == 0} then}\\
|
|
661 |
$\bullet$ & $\texttt{pc} + 1$\\
|
|
662 |
$\bullet$ & $\texttt{mp}$ and \texttt{mem} unchanged\\
|
|
663 |
\end{tabular}\\\hline
|
|
664 |
any other char & \begin{tabular}[t]{@{}l@{\hspace{2mm}}l@{}}
|
|
665 |
$\bullet$ & $\texttt{pc} + 1$\\
|
|
666 |
$\bullet$ & \texttt{mp} and \texttt{mem} unchanged
|
|
667 |
\end{tabular}\\
|
|
668 |
\hline |
|
669 |
\end{tabular}
|
|
670 |
\end{center}
|
|
671 |
\caption{The rules for how commands in the brainf*** language update the program counter \texttt{pc},
|
|
672 |
memory pointer \texttt{mp} and memory \texttt{mem}.\label{comms}}
|
|
673 |
\end{figure}
|
|
674 |
\end{itemize}\bigskip
|
|
675 |
||
676 |
||
677 |
||
| 6 | 678 |
|
679 |
\end{document}
|
|
680 |
||
| 68 | 681 |
|
| 6 | 682 |
%%% Local Variables: |
683 |
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|
684 |
%%% TeX-master: t |
|
685 |
%%% End: |