239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
1 |
\documentclass{article}
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Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
2 |
\usepackage{../style}
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Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
3 |
\usepackage{../langs}
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Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
4 |
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Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
5 |
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Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
6 |
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Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
7 |
\begin{document}
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Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
8 |
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Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
9 |
\section*{A Crash-Course on Notation}
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Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
10 |
|
398
Christian Urban <christian dot urban at kcl dot ac dot uk>
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|
11 |
There are innumerable books available about compiler, automata
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Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
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|
12 |
and formal languages. Unfortunately, they often use their own
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
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|
13 |
notational conventions and their own symbols. This handout is
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
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|
14 |
meant to clarify some of the notation I will use.
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
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|
15 |
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239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
16 |
\subsubsection*{Characters and Strings}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
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|
17 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
18 |
The most important concept in this module are strings. Strings
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
19 |
are composed of \defn{characters}. While characters are surely
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
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|
20 |
a familiar concept, we will make one subtle distinction in
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
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|
21 |
this module. If we want to refer to concrete characters, like
|
332
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
22 |
\code{a}, \code{b}, \code{c} and so on, we use a typewriter font.
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
23 |
Accordingly if we want to refer to the concrete characters of
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
24 |
my email address we shall write
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
25 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
26 |
\begin{center}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
27 |
\pcode{christian.urban@kcl.ac.uk}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
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|
28 |
\end{center}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
29 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
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|
30 |
\noindent If we also need to explicitly indicate the ``space''
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
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|
31 |
character, we write \VS{}\hspace{1mm}. For example
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
32 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
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|
33 |
\begin{center}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
34 |
\tt{}hello\VS\hspace{0.5mm}world
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
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|
35 |
\end{center}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
36 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
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|
37 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
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|
38 |
\noindent But often we do not care which particular characters
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
39 |
we use. In such cases we use the italic font and write $a$,
|
332
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
40 |
$b$, $c$ and so on for characters. Therefore if we need a
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
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|
41 |
representative string, we might write
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
42 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
43 |
\begin{equation}\label{abracadabra}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
44 |
abracadabra
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
45 |
\end{equation}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
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|
46 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
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|
47 |
\noindent In this string, we do not really care what the
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
48 |
characters stand for, except we do care about the fact that
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
49 |
for example the character $a$ is not equal to $b$ and so on.
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
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|
50 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
51 |
An \defn{alphabet} is a (non-empty) finite set of characters.
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
52 |
Often the letter $\Sigma$ is used to refer to an alphabet. For
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
53 |
example the ASCII characters \pcode{a} to \pcode{z} form an
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
54 |
alphabet. The digits $0$ to $9$ are another alphabet. The
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
55 |
Greek letters $\alpha$ to $\omega$ also form an alphabet. If
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
56 |
nothing else is specified, we usually assume the alphabet
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
57 |
consists of just the lower-case letters $a$, $b$, \ldots, $z$.
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
58 |
Sometimes, however, we explicitly want to restrict strings to
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
59 |
contain only the letters $a$ and $b$, for example. In this
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
60 |
case we will state that the alphabet is the set $\{a, b\}$.
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
61 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
62 |
\defn{Strings} are lists of characters. Unfortunately, there
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
63 |
are many ways how we can write down strings. In programming
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
64 |
languages, they are usually written as \dq{$hello$} where the
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
65 |
double quotes indicate that we are dealing with a string. But
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
66 |
since we regard strings as lists of characters we could also
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
67 |
write this string as
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
68 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
69 |
\[
|
332
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
70 |
[\text{\it h, e, l, l, o}] \;\;\text{or simply}\;\; \textit{hello}
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
71 |
\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
72 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
73 |
\noindent The important point is that we can always decompose
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
74 |
such strings. For example, we will often consider the first
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
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|
75 |
character of a string, say $h$, and the ``rest'' of a string
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
76 |
say \dq{\textit{ello}} when making definitions about strings.
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
77 |
There are also some subtleties with the empty string,
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
78 |
sometimes written as \dq{} but also as the empty list of
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
79 |
characters $[\,]$.\footnote{In the literature you can also
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
80 |
often find that $\varepsilon$ or $\lambda$ is used to
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
81 |
represent the empty string.}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
82 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
83 |
Two strings, say $s_1$ and $s_2$, can be \defn{concatenated},
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
84 |
which we write as $s_1 @ s_2$. Suppose we are given two
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
85 |
strings \dq{\textit{foo}} and \dq{\textit{bar}}, then their
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
86 |
concatenation, writen \dq{\textit{foo}} $@$ \dq{\textit{bar}},
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
87 |
gives \dq{\textit{foobar}}. Often we will simplify our life
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
88 |
and just drop the double quotes whenever it is clear we are
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
89 |
talking about strings, writing as already in
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
90 |
\eqref{abracadabra} just \textit{foo}, \textit{bar},
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
91 |
\textit{foobar} or \textit{foo $@$ bar}.
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
92 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
93 |
Some simple properties of string concatenation hold. For
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
94 |
example the concatenation operation is \emph{associative},
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
95 |
meaning
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
96 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
97 |
\[(s_1 @ s_2) @ s_3 = s_1 @ (s_2 @ s_3)\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
98 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
99 |
\noindent are always equal strings. The empty string behaves
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
100 |
like a unit element, therefore
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
101 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
102 |
\[s \,@\, [] = [] \,@\, s = s\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
103 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
104 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
105 |
Occasionally we will use the notation $a^n$ for strings, which
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
106 |
stands for the string of $n$ repeated $a$s. So $a^{n}b^{n}$ is
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
107 |
a string that has as many $a$s as $b$s.
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
108 |
|
246
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
109 |
Note however that while for us strings are just lists of
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
110 |
characters, programming languages often differentiate between
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
111 |
the two concepts. In Scala, for example, there is the type of
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
112 |
\code{String} and the type of lists of characters,
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
113 |
\code{List[Char]}. They are not the same and we need to
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
114 |
explicitly coerce elements between the two types, for example
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
115 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
116 |
\begin{lstlisting}[numbers=none]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
117 |
scala> "abc".toList
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
118 |
res01: List[Char] = List(a, b, c)
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
119 |
\end{lstlisting}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
120 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
121 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
122 |
\subsubsection*{Sets and Languages}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
123 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
124 |
We will use the familiar operations $\cup$, $\cap$, $\subset$
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
125 |
and $\subseteq$ for sets. For the empty set we will either
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
126 |
write $\varnothing$ or $\{\,\}$. The set containing the
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
127 |
natural numbers $1$, $2$ and $3$, for example, we will write
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
128 |
with curly braces as
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
129 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
130 |
\[
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
131 |
\{1, 2, 3\}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
132 |
\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
133 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
134 |
\noindent The notation $\in$ means \emph{element of}, so $1
|
266
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
135 |
\in \{1, 2, 3\}$ is true and $4 \in \{1, 2, 3\}$ is false.
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
136 |
Sets can potentially have infinitely many elements. For
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
137 |
example the set of all natural numbers $\{0, 1, 2, \ldots\}$
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
138 |
is infinite. This set is often also abbreviated as
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
139 |
$\mathbb{N}$. We can define sets by giving all elements, for
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
140 |
example $\{0, 1\}$, but also by \defn{set comprehensions}. For
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
141 |
example the set of all even natural numbers can be defined as
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
142 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
143 |
\[
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
144 |
\{n\;|\;n\in\mathbb{N} \wedge n\;\text{is even}\}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
145 |
\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
146 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
147 |
\noindent Though silly, but the set $\{0, 1, 2\}$ could also be
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
148 |
defined by the following set comprehension
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
149 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
150 |
\[
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
151 |
\{n\;|\; n^2 < 9 \wedge n \in \mathbb{N}\}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
152 |
\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
153 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
154 |
\noindent Notice that set comprehensions could be used
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
155 |
to define set union, intersection and difference:
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
156 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
157 |
\begin{eqnarray*}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
158 |
A \cup B & \dn & \{x\;|\; x \in A \vee x \in B\}\\
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
159 |
A \cap B & \dn & \{x\;|\; x \in A \wedge x \in B\}\\
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
160 |
A \backslash B & \dn & \{x\;|\; x \in A \wedge x \not\in B\}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
161 |
\end{eqnarray*}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
162 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
163 |
\noindent In general set comprehensions are of the form
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
164 |
$\{a\;|\;P\}$ which stands for the set of all elements $a$
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
165 |
(from some set) for which some property $P$ holds.
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
166 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
167 |
For defining sets, we will also often use the notion of the
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
168 |
``big union''. An example is as follows:
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
169 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
170 |
\begin{equation}\label{bigunion}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
171 |
\bigcup_{0\le n}\; \{n^2, n^2 + 1\}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
172 |
\end{equation}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
173 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
174 |
\noindent which is the set of all squares and their immediate
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
175 |
successors, so
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
176 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
177 |
\[
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
178 |
\{0, 1, 2, 4, 5, 9, 10, 16, 17, \ldots\}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
179 |
\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
180 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
181 |
\noindent A big union is a sequence of unions which are
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
182 |
indexed typically by a natural number. So the big union in
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
183 |
\eqref{bigunion} could equally be written as
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
184 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
185 |
\[
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
186 |
\{0, 1\} \cup \{1, 2\} \cup \{4, 5\} \cup \{9, 10\} \cup
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
187 |
\ldots
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
188 |
\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
189 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
190 |
\noindent but using the big union notation is more concise.
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
191 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
192 |
An important notion in this module are \defn{languages}, which
|
398
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
193 |
are sets of strings. One of the main goals for us will be how to
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
194 |
(formally) specify languages and to find out whether a string
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
195 |
is in a language or not.\footnote{You might wish to ponder
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
196 |
whether this is in general a hard or easy problem, where
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
197 |
hardness is meant in terms of Turing decidable, for example.}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
198 |
Note that the language containing the empty string $\{\dq{}\}$
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
199 |
is not equal to $\varnothing$, the empty language (or empty
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
200 |
set): The former contains one element, namely \dq{} (also
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
201 |
written $[\,]$), but the latter does not contain any
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
202 |
element.
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
203 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
204 |
For languages we define the operation of \defn{language
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
205 |
concatenation}, written like in the string case as $A @ B$:
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
206 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
207 |
\begin{equation}\label{langconc}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
208 |
A @ B \dn \{s_1 @ s_2\;|\; s_1\in A \wedge s_2\in B\}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
209 |
\end{equation}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
210 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
211 |
\noindent Be careful to understand the difference: the $@$
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
212 |
in $s_1 @ s_2$ is string concatenation, while $A @ B$ refers
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
213 |
to the concatenation of two languages (or sets of strings).
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
214 |
As an example suppose $A=\{ab, ac\}$ and $B=\{zzz, qq, r\}$,
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
215 |
then $A \,@\, B$ is the language
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
216 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
217 |
\[
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
218 |
\{abzzz, abqq, abr, aczzz, acqq, acr\}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
219 |
\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
220 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
221 |
\noindent Recall the properties for string concatenation. For
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
222 |
language concatenation we have the following properties
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
223 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
224 |
\begin{center}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
225 |
\begin{tabular}{ll}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
226 |
associativity: & $(A @ B) @ C = A @ (B @ C)$\\
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
227 |
unit element: & $A \,@\, \{[]\} = \{[]\} \,@\, A = A$\\
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
228 |
zero element: & $A \,@\, \varnothing = \varnothing \,@\, A =
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
229 |
\varnothing$
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
230 |
\end{tabular}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
231 |
\end{center}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
232 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
233 |
\noindent Note the difference in the last two lines: the empty
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
234 |
set behaves like $0$ for multiplication and the set $\{[]\}$
|
242
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
235 |
like $1$ for multiplication ($n * 1 = n$ and $n * 0 = 0$).
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
236 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
237 |
Following the language concatenation, we can define a
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
238 |
\defn{language power} operation as follows:
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
239 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
240 |
\begin{eqnarray*}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
241 |
A^0 & \dn & \{[]\}\\
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
242 |
A^{n+1} & \dn & A \,@\, A^n
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
243 |
\end{eqnarray*}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
244 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
245 |
\noindent This definition is by recursion on natural numbers.
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
246 |
Note carefully that the zero-case is not defined as the empty
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
247 |
set, but the set containing the empty string. So no matter
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
248 |
what the set $A$ is, $A^0$ will always be $\{[]\}$. (There is
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
249 |
another hint about a connection between the $@$-operation and
|
242
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
250 |
multiplication: How is $x^n$ defined recursively and what is
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
251 |
$x^0$?)
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
252 |
|
242
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
253 |
Next we can define the \defn{star operation} for languages:
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
254 |
$A^*$ is the union of all powers of $A$, or short
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
255 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
256 |
\begin{equation}\label{star}
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
257 |
A^* \dn \bigcup_{0\le n}\; A^n
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
258 |
\end{equation}
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
259 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
260 |
\noindent This star operation is often also called
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
261 |
\emph{Kleene-star}. Unfolding the definition in \eqref{star}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
262 |
gives
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
263 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
264 |
\[
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
265 |
A^0 \cup A^1 \cup A^2 \cup A^3 \cup \ldots
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
266 |
\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
267 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
268 |
\noindent
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
269 |
which is equal to
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
270 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
271 |
\[
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
272 |
\{[]\} \,\cup\, A \,\cup\, A @ A \,\cup\, A @ A @ A \,\cup\, \ldots
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
273 |
\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
274 |
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
275 |
\noindent We can see that the empty string is always in $A^*$,
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
276 |
no matter what $A$ is. This is because $[] \in A^0$. To make
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
277 |
sure you understand these definitions, I leave you to answer
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
278 |
what $\{[]\}^*$ and $\varnothing^*$ are.
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
279 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
280 |
Recall that an alphabet is often referred to by the letter
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
281 |
$\Sigma$. We can now write for the set of all strings over
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
282 |
this alphabet $\Sigma^*$. In doing so we also include the
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
283 |
empty string as a possible string over $\Sigma$. So if
|
241
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
284 |
$\Sigma = \{a, b\}$, then $\Sigma^*$ is
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
285 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
286 |
\[
|
246
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
287 |
\{[], a, b, aa, ab, ba, bb, aaa, aab, aba, abb, baa, bab, \ldots\}
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
288 |
\]
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
289 |
|
246
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
290 |
\noindent or in other words all strings containing $a$s and
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
diff
changeset
|
291 |
$b$s only, plus the empty string.
|
239
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
292 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
293 |
\end{document}
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
294 |
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
295 |
%%% Local Variables:
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
296 |
%%% mode: latex
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
297 |
%%% TeX-master: t
|
Christian Urban <christian dot urban at kcl dot ac dot uk>
parents:
diff
changeset
|
298 |
%%% End:
|