# Finite state automata as (programming) language acceptors

I know how a FSA accepts the string 'nice' (as shown in the Wikipedia page) but how can the language that a FSA accepts be a programming language?

Is it like this?; lets say that I have an alphabet A={1,2,+,-} and language L={1+1,1+2,1-1,1-2} then my FSA looks like this;

``````-->[1]--1-->[2]--+-->[3]--1-->[[5]]
|        |
-        2-->[[6]]
|
v
[4]--1-->[[7]]
|
2-->[[8]]
``````

When I reach the accepting states 5, 6, 7, 8 I know what the value should be and therefore I have defined a programming language???

And if I extend it to have nested FSAs then I can compute strings like '1plus2' and 'sqrt(9)'.

Is this thinking correct?

-
Is there such a thing as a "nested FSA"? My impression was that (unbounded) nesting leads to infinite states. –  delnan Jan 12 '12 at 20:54
Well my knowledge is lacking in this, the nested FSA would actually probably be more like a Turing machine, I was just thinking of a way to run sub routines within the FSA, this may well be impossible but my real question is how can a FSA act as a programming language acceptor? I know how languages are accepted but how are they acted upon, ie when I hit state 5 how do I know that I have the value 2 in order to be able to store it in a register or do whatever I need to do with it? It seems to me that extending it in any way makes it no longer a FSA. –  Neilos Jan 12 '12 at 21:02
To compute A+B=C takes more than a finite state automaton, for the simple reason that the language a^n b^m c^(n+m) isn't a regular language, by the pumping lemma. –  Patrick87 Jan 12 '12 at 21:09

No, that's not quite right. To understand how FSAs are related to computation, you need to adopt a more general view of computation.

Generally speaking, computation is about taking input and producing output. For now, let's focus on one kind of problem we can compute the answer to: decision problems, where the output is restricted to "yes" or "no". Let's further restrict the kinds of problems we're talking about to those decisions problems whose inputs are strings (like "nice"). These are precisely the kinds of questions that FSAs can be used to answer (but they can't answer all of them!).

So FSAs can answer (some) questions of the following form: does string X possess property Y? Examples of this are "Is the string one of a known, finite set of strings?", "Is the string the binary representation of an odd number?", "Does the string have 'cat' as a substring?". These can all be answered by FSAs.

Your problems - like 1+1 - is not a decision problem. You can make it a decision problem, though, as follows: "Is my string of the form 'x+y=z', where x, y and z are decimal representations of integers X, Y and Z and X + Y = Z?" This question, and many like it, cannot be answered using FSAs.

Stronger kinds of state machines exist; they are not "finite". Examples include pushdown automata (PDAs), linear-bounded automata (LBAs) and Turing machines (TMs). There are some decision problems of the form "does string X possess property Y?" that not even Turing machines, the most powerful known kind of automata, cannot answer. One example is given by the halting problem: "Given 'x(y)' where x is a program and y is an input to the program, does the program represented by X halt when passed the input y?". There is no TM - that is, no algorithm - to answer this question in the general case.

Can you write an FSA that answers the question "Is the string x a syntactically valid string in this language I'm defining?" Naturally, that depends on the rules of your language. Strings of the form "Number + Number + ... + Number" can be recognized by an FSA, but an FSA can't tell you what the sum is. However, you can't add parentheses to this, or else FSAs are no longer adequate. In other words, there is a difference between recognizing strings and computing results, and FSAs typically are thought of as doing the former.

Please feel free to ask any additional questions. If you're interested in these kinds of questions, please show support for the new Computer Science StackExchange by visiting the following site and committing:

http://area51.stackexchange.com/proposals/35636/computer-science-non-programming?referrer=rpnXA1_2BNYzXN85c5ibxQ2

-
Thank you for your answer. It was put to me that FSA have been shown to act as (programming) language acceptors, is it the case then that it is true but only in a (very) limited case? –  Neilos Jan 12 '12 at 21:11
@Neilos: Essentially, yes: finite state automata recognize the regular languages, which are a subset of the context free languages, which are a subset of the context-sensitive languages, which are a subset of the languages accepted by Turing machines, which are a subset of the set of all possible languages over an alphabet. The automata that go with these (where applicable) are increasingly powerful. The idea of actually computing (rather than deciding) begins with TMs, PDAs at the earliest (if you want to leave the result on the stack)... maybe Moore/Mealy machines are a limited form. –  Patrick87 Jan 12 '12 at 21:14