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\section*{Homework 2}
\HEADER
\begin{enumerate}
\item What is the difference between \emph{basic} regular expressions
and \emph{extended} regular expressions?
\solution{Basic regular expressions are $\ZERO$, $\ONE$, $c$, $r_1 + r_2$,
$r_1 \cdot r_2$, $r^*$. The extended ones are the bounded
repetitions, not, etc.}
\item What is the language recognised by the regular
expressions $(\ZERO^*)^*$.
\solution{$L(\ZERO^*{}^*) = \{[]\}$,
remember * always includes the empty string}
\item Review the first handout about sets of strings and read
the second handout. Assuming the alphabet is the set
$\{a, b\}$, decide which of the following equations are
true in general for arbitrary languages $A$, $B$ and
$C$:
\begin{eqnarray}
(A \cup B) @ C & =^? & A @ C \cup B @ C\nonumber\\
A^* \cup B^* & =^? & (A \cup B)^*\nonumber\\
A^* @ A^* & =^? & A^*\nonumber\\
(A \cap B)@ C & =^? & (A@C) \cap (B@C)\nonumber
\end{eqnarray}
\noindent In case an equation is true, give an
explanation; otherwise give a counter-example.
\solution{1 + 3 are equal; 2 + 4 are not. Interesting is 4 where
$A = \{[a]\}$, $B = \{[]\}$ and $C = \{[a], []\}$\medskip
For equations like 3 it is always a god idea to prove the
two inclusions
\[
A^* \subseteq A^* @ A^* \qquad
A^* @ A^* \subseteq A^*
\]
This means for every string $s$ we have to show
\[
s \in A^* \;\textit{implies}\; s \in A^* @ A^* \qquad
s \in A^* @ A^* \;\textit{implies}\; s \in A^*
\]
The first one is easy because $[] \in A^*$ and therefore
$s @ [] \in A^* @ A^*$.
The second one says that $s$ must be of the form $s = s_1 @ s_2$ with
$s_1 \in A^*$ and $s_2 \in A^*$. We have to show that
$s_1 @ s_2 \in A^*$.
If $s_1 \in A^*$ then there exists an $n$ such that $s_1 \in A^n$, and
if $s_2 \in A^*$ then there exists an $m$ such that $s_2 \in A^m$.\bigskip
Aside: We are going to show that
\[
A^n \,@\, A^m = A^{n+m}
\]
We prove that by induction on $n$.
Case $n = 0$: $A^0 \,@\, A^m = A^{0+m}$ holds because $A^0 = \{[]\}$
and $\{[]\} \,@\, A^m = A ^ m$ and $0 + m = m$.\medskip
Case $n + 1$: The induction hypothesis is
\[ A^n \,@\, A^m = A^{n+m}
\]
We need to prove
\[
A^{n+1} \,@\, A^m = A^{(n+1)+m}
\]
The left-hand side is $(A \,@\, A^n) \,@\, A^m$ by the definition of
the power operation. We can rearrange that
to $A \,@\, (A^n \,@\, A^m)$. \footnote{Because for all languages $A$, $B$, $C$ we have $(A @ B) @ C = A @ (B @ C)$.}
By the induction hypothesis we know that $A^n \,@\, A^m = A^{n+m}$.
So we have $A \,@\, (A^{n+m})$. But this is $A^{(n+m)+1}$ again if we
apply the definition of the power operator. If we
rearrange that we get $A^{(n+1)+m}$ and are done with
what we need to prove for the power law.\bigskip
Picking up where we left, we know that $s_1 \in A^n$ and $s_2 \in A^m$. This now implies that $s_1 @ s_2\in A^n @ A^m$. By the power law this means
$s_1 @ s_2\in A^{n+m}$. But this also means $s_1 @ s_2\in A^*$.
}
\item Given the regular expressions $r_1 = \ONE$ and $r_2 =
\ZERO$ and $r_3 = a$. How many strings can the regular
expressions $r_1^*$, $r_2^*$ and $r_3^*$ each match?
\solution{$r_1$ and $r_2$ can match the empty string only, $r_3$ can
match $[]$, $a$, $aa$, ....}
\item Give regular expressions for (a) decimal numbers and for
(b) binary numbers. Hint: Observe that the empty string
is not a number. Also observe that leading 0s are
normally not written---for example the JSON format for numbers
explicitly forbids this. So 007 is not a number according to JSON.
\solution{Just numbers without leading 0s: $0 + (1..9)\cdot(0..1)^*$;
can be extended to decimal; similar for binary numbers
}
\item Decide whether the following two regular expressions are
equivalent $(\ONE + a)^* \equiv^? a^*$ and $(a \cdot
b)^* \cdot a \equiv^? a \cdot (b \cdot a)^*$.
\solution{Both are equivalent, but why the second? Essentially you have to show that each string in one set is in the other. For 2 this means you can do an induction proof that $(ab)^na$ is the same string as $a(ba)^n$, where the former is in the first set and the latter in the second.}
\item Given the regular expression $r = (a \cdot b + b)^*$.
Compute what the derivative of $r$ is with respect to
$a$, $b$ and $c$. Is $r$ nullable?
\item Give an argument for why the following holds:
if $r$ is nullable then $r^{\{n\}} \equiv r^{\{..n\}}$.
\solution{This was from last week; I just explicitly added it here.}
\item Define what is meant by the derivative of a regular
expressions with respect to a character. (Hint: The
derivative is defined recursively.)
\solution{the recursive function for $der$}
\item Assume the set $Der$ is defined as
\begin{center}
$Der\,c\,A \dn \{ s \;|\; c\!::\!s \in A\}$
\end{center}
What is the relation between $Der$ and the notion of
derivative of regular expressions?
\solution{Main property is $L(der\,c\,r) = Der\,c\,(L(r))$.}
\item Give a regular expression over the alphabet $\{a,b\}$
recognising all strings that do not contain any
substring $bb$ and end in $a$.
\solution{$((ba)^* \cdot (a)^*)^*\,\cdot\,a$}
\item Do $(a + b)^* \cdot b^+$ and $(a^* \cdot b^+) +
(b^*\cdot b^+)$ define the same language?
\solution{No, the first one can match for example abababababbbbb
while the second can only match for example aaaaaabbbbb or bbbbbbb}
\item Define the function $zeroable$ by recursion over regular
expressions. This function should satisfy the property
\[
zeroable(r) \;\;\text{if and only if}\;\;L(r) = \{\}\qquad(*)
\]
The function $nullable$ for the not-regular expressions
can be defined by
\[
nullable(\sim r) \dn \neg(nullable(r))
\]
Unfortunately, a similar definition for $zeroable$ does
not satisfy the property in $(*)$:
\[
zeroable(\sim r) \dn \neg(zeroable(r))
\]
Find a counter example?
\solution{
Here the idea is that nullable for NOT can be defined as
\[nullable(\sim r) \dn \neg(nullable(r))\]
This will satisfy the property
$nullable(r) \;\;\text{if and only if}\;\;[] \in L(r)$. (Remember how
$L(\sim r)$ is defined).\bigskip
But you cannot define
\[zeroable(\sim r) \dn \neg(zeroable(r))\]
because if $r$ for example is $\ONE$ then $\sim \ONE$ can match
some strings (all non-empty strings). So $zeroable$ should be false. But if we follow
the above definition we would obtain $\neg(zeroable(\ONE))$. According
to the definition of $zeroable$ for $\ONE$ this would be false,
but if we now negate false, we get actually true. So the above
definition would not satisfy the property
\[
zeroable(r) \;\;\text{if and only if}\;\;L(r) = \{\}
\]
}
\item Give a regular expressions that can recognise all
strings from the language $\{a^n\;|\;\exists k.\; n = 3 k
+ 1 \}$.
\solution{$a(aaa)^*$}
\item Give a regular expression that can recognise an odd
number of $a$s or an even number of $b$s.
\solution{
If the a's and b's are meant to be separate, then this is easy
\[a(aa)^* + (bb)^*\]
If the letters are mixed, then this is difficult
\[(aa|bb|(ab|ba)\cdot (aa|bb)^* \cdot (ba|ab))^* \cdot (b|(ab|ba)(bb|aa)^* \cdot a)
\]
(copied from somewhere ;o)
The idea behind it is essentially the DFA
\begin{center}
\begin{tikzpicture}[scale=1,>=stealth',very thick,
every state/.style={minimum size=0pt,
draw=blue!50,very thick,fill=blue!20}]
\node[state,initial] (q0) at (0,2) {$q_0$};
\node[state,accepting] (q1) at (2,2) {$q_1$};
\node[state] (q2) at (0,0) {$q_2$};
\node[state] (q3) at (2,0) {$q_3$};
\path[->] (q0) edge[bend left] node[above] {$a$} (q1)
(q1) edge[bend left] node[above] {$a$} (q0)
(q2) edge[bend left] node[above] {$a$} (q3)
(q3) edge[bend left] node[above] {$a$} (q2)
(q0) edge[bend left] node[right] {$b$} (q2)
(q2) edge[bend left] node[left] {$b$} (q0)
(q1) edge[bend left] node[right] {$b$} (q3)
(q3) edge[bend left] node[left] {$b$} (q1);
\end{tikzpicture}
\end{center}
}
\item \POSTSCRIPT
\end{enumerate}
\end{document}
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