# Tag Info

29

DFAs and NFAs have exactly the same capabilities and limitations. The only difference is notational convenience. A finite automaton is a processor that has states and reads input, each input character potentially setting it into another state. For example, a state might be "just read two Cs in a row" or "am starting a word". These are usually used for ...

18

Short version for general approach. There's an algo out there called the Thompson-McNaughton-Yamada Construction Algorithm or sometimes just "Thompson Construction." One builds intermediate NFAs, filling in the pieces along the way, while respecting operator precedence: first parentheses, then Kleene Star (e.g., a*), then concatenation (e.g., ab), followed ...

15

As you says in question: I know that to convert a DFA, M to the complement, M`, I just need to swap the initial accepting states and final accepting states. Its not complement, but you are doing something like reverse of a language and regular languages are closure under reversal. Reversal of DFA What is the Reversal Language ? The ...

11

When you construct a DFA from an NFA you basically find those sets of states that the NFA can be in a time (like simulating the NFA). First you begin with the start state and then find all states that can be reached through epsilon transitions. This set of states form the start state of the resulting DFA. Then you follow the outgoing transitions from this ...

8

Take a look at my series of posts about this subject: Regular Expression Engine in C# (the Story) Regex engine in C# - the Regex Parser Regex engine in C# - the NFA Regex engine in C# - the DFA Regex engine in C# - matching strings

7

Regular Expression to DFA Although there is NO algorithmic shortcut to draw DFA from a Regular Expression(RE) but a shortcut technique is possible by analysis not by derivation, it can save your time to draw a minimized dfa. But off-course the technique you can learn only by practice. I take your example to show my approach: (a + b)*ab First, ...

6

I think you've pretty much nailed the main tradeoffs on the head. NFAs can be more memory efficient because they can encode O(2n) different configurations in O(n) space, whereas a DFA for the same language might take exponential space. You're similarly correct that NFAs have slower updates; most algorithms for simulating NFAs take O(n) time to compute ...

6

Here's a non-technical answer from Microsoft: DFA engines run in linear time because they do not require backtracking (and thus they never test the same character twice). They can also guarantee matching the longest possible string. However, since a DFA engine contains only finite state, it cannot match a pattern with backreferences, and because it does not ...

5

Nope. A real number can have an infinite number of digits behind the decimal point. There may not be a system in those digits (i.e., they may be generated by a random process). In that case there cannot be a description of this sequence of digits that is significantly shorter than the sequence itself. Now take such a real number r. Since any NFA has only a ...

5

Edited to take into account comments by @amon (thank you, by the way) Your assignment statement... my \$var = "SRC=array.c builtin.c eval.c field.c gawkmisc.c io.c main.c \ missing.c msg.c node.c re.c version.c"; ... Contains a backslash followed by a newline. The backslash, when used within a string contained in double quotes, functions to escape the ...

4

The core idea Is probably to understand that the DFA is a sort of machine that is superimposed over the NFA. While the NFA is simpler in terms of the number of nodes, or its relationship with the problem, it's rules are quite subtle and compled (it goes into the right state, whichever that might be). The dfa is much more complex in terms of the nodes it ...

4

NFA. See Friedl's Mastering Regular Expressions, 3rd edition, chapter 4 - table 4-1, page 145. Google books has a preview to it.

4

You want to do; for each char in input: next = { } for each state in current: for each transition in transitions[state][char]: next.append(target_of(transition)) current = next but what you're doing is; for each char in input: next = { } for each state in current: for each transition in ...

4

Let your original DFA be called M1. To put it in simple terms, constructing a minimized DFA (call it M2) implies converting it into a DFA that contains minimum number of states. So, the number of states in M2 will be less than number of states in M1. An important point to note here is that M1 and M2 have to be equivalent, which means that they must define ...

4

Your proposed algorithm does not do a full minimization, because it does not detect complex structures that behave identically. To understand this look at this DFA (drawn by JFLAP): Minimization would combine q1 and q2, but the outlined algorithm does not manage to. In contrast to this, Hopcroft's algorithm would initially partition like this: {q0, ...

4

I've written an article on this subject. Converting a NFA to a DFA by subset construction It includes pseudocode on how to do the transformation as well. Basically the algorithm is, starting with the starting state of the NFA: Perform closure on the current state set For each input symbol do the GOTO operation on the closure set. If the state set ...

4

If we replace character c with x where (x ∈ {a,b}+), say, L2 = {WXWR| x, W ∈ {a,b}+}, then L2 is a regular language. Yes, L2 is Regular Language :). You can write regular expression for L2 too. Language L2 = {WXWR| x, W ∈ {a,b}+} means: string should start any string consist of a and b that is W and end with reverse string WR. notice: ...

3

Since this is very likely homework, I'm hesitant to just give you the complete correct solution. Your NFA appears correct, but has a lot of superfluous states that aren't necessary but do not adversely affect its correctness. (At first glance it looks like you could remove 11 states.) Your DFA is incorrect, though. This is because when you branch off to ...

3

Your NFA matches the same language as (a*|b*)*, so the answer is correct. However, there are many NFAs that match the same language and in your case it would be possible to remove at least three epsilon arrows. Still, it will not be more correct than your suggestion. The regex (a*|b*)* can also be simplified, without changing the semantics. E.g. (a|b)* is ...

3

A simple, nontechnical explanation, paraphrased from Jeffrey Friedl's book Mastering Regular Expressions. CAVEAT: While this book is generally considered the "regex bible", there appears some controversy as to whether the distinction made here between DFA and NFA is actually correct. I'm not a computer scientist, and I don't understand most of the theory ...

3

You can use the GDL (Graph Description Language) to do this: Graph Description Language You may also be interested in DOT, which is a plain text graph description language: DOT

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First, a note about terminology: A language is a set of strings over some alphabet. DFAs and NFAs recognize regular languages, not regular expressions. There may be several regular expressions that define the same language. For two languages L1 and L2, if every member of L1 is a member of L2, and vice versa, than L1 and L2 are equivalent. Regarding your ...

3

If it's a black box, then give it some input and measure its time characteristics with a pathological case, with reference to the graphs in this discussion of NFS vs backtracking regex implementations. (note the NFS graph is microseconds not seconds). Also, if it's a pure NFA, then it won't have some non-regular features which are found is some 'regular ...

3

(Since this is a homework problem, I'm assuming that you just want enough help to get started, and not a full worked solution?) Your mileage may vary, but I don't really recommend trying to convert an NFA into a regular expression. The two are theoretically equivalent, and either can be converted into the other algorithmically, but in my opinion, it's not ...

3

Evaluating an NFA is almost as easy as evaluating a DFA. In a DFA, you have one current state and in each step you select the next transition. At the end of the input, you check whether the current state is an accepting state. Well, in an NFA you have a set of current states, and in each step you go through all current states, and for each, you select all ...

3

I start with fundamental with your example so that one can find it helpful Any class of automata can have two forms: Deterministic Non-Deterministic. In Deterministic model: we only have single choice (or say no choice) to move from one congratulation to next configuration. In Deterministic model of Finite Automate (DFA): for every possible ...

2

NFAs and DFAs accept equivalent (regular) languages, so one way to show that a language is regular is to create an NFA or DFA for it. To show that a language is not in a class, you typically would use the pumping lemma. Wikipedia has a very similar example, except n>=0; I won't finish your homework for you, though. ...

2

There are a number of ways to handle it. They all boil down to treating sets of characters at a time in the data structures, instead of enumerating the entire alphabet ever at all. It's also how you make scanners for Unicode in a reasonable amount of memory. You've many choices about how to represent and process sets of characters. I'm presently working ...

2

Addressing your need to speed up your regexes: Java's implementation of its regex engine is NFA based. As such, to tune your regexes, I would say that you would benefit from a deeper understanding of how the engine is implemented. And as such I direct you to: Mastering Regular Expressions The book gives substantial treatment to the NFA engine and how it ...

2

This is the implementation from OpenFst. In this paper is a diagram (page 15) that show results of applying the reverse operation. An easier way to help understand FSM operations is to use a library like OpenFst to create and manipulable the machines and then visualize the results using Graphviz.

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