In the context of computer science, a *word* is the concatenation of *symbols*. The used symbols are called the *alphabet*. For example, some words formed out of the alphabet `{0,1,2,3,4,5,6,7,8,9}`

would be `1`

, `2`

, `12`

, `543`

, `1000`

, and `002`

.

A *language* is then a subset of all possible words. For example, we might want to define a language that captures all elite MI6 agents. Those all start with double-0, so words in the language would be `007`

, `001`

, `005`

, and `0012`

, but not `07`

or `15`

. For simplicity's sake, we say a language is "*over* an alphabet" instead of "a subset of words formed by concatenation of symbols *in* an alphabet".

In computer science, we now want to classify languages. We call a language *regular* if it can be decided if a word is in the language with an algorithm/a machine with constant (finite) memory by examining all symbols in the word one after another. The language consisting just of the word `42`

is regular, as you can decide whether a word is in it without requiring arbitrary amounts of memory; you just check whether the first symbol is 4, whether the second is 2, and whether any more numbers follow.

All languages with a finite number of words are regular, because we can (in theory) just build a control flow tree of constant size (you can visualize it as a bunch of nested `if`

-statements that examine one digit after the other). For example, we can test whether a word is in the "prime numbers between 10 and 99" language with the following construct, requiring no memory except the one to encode at which code line we're currently at:

```
if word[0] == 1:
if word[1] == 1: # 11
return true # "accept" word, i.e. it's in the language
if word[1] == 3: # 13
return true
...
return false
```

Note that all finite languages are regular, but not all regular languages are finite; our double-0 language contains an infinite number of words (`007`

, `008`

, but also `004242`

and `0012345`

), but can be tested with constant memory: To test whether a word belongs in it, check whether the first symbol is `0`

, and whether the second symbol is `0`

. If that's the case, accept it. If the word is shorter than three or does not start with `00`

, it's not an MI6 code name.

Formally, the construct of a finite-state machine or a regular grammar is used to prove that a language is regular. These are similar to the `if`

-statements above, but allow for arbitrarily long words. If there's a finite-state machine, there is also a regular grammar, and vice versa, so it's sufficient to show either. For example, the finite state machine for our double-0 language is:

```
start state: if input = 0 then goto state 2
start state: if input = 1 then fail
start state: if input = 2 then fail
...
state 2: if input = 0 then accept
state 2: if input != 0 then fail
accept: for any input, accept
```

The equivalent regular grammar is:

```
start → 0 B
B → 0 accept
accept → 0 accept
accept → 1 accept
...
```

The equivalent regular expression is:

```
00[0-9]*
```

Some languages are *not* regular. For example, the language of any number of `1`

, followed by the same number of `2`

(often written as 1^{n}2^{n}, for an arbitrary *n*) is not regular - you need more than a constant amount of memory (= a constant number of states) to store the number of `1`

s to decide whether a word is in the language.

This should usually be explained in the theoretical computer science course. Luckily, Wikipedia explains both formal and regular languages quite nicely.

`a*b*`

is regular? But language { a^nb^n | n > 0 } is not a regular language