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I'm reading through the dragon book and trying to solve an exercise that is stated as follows

Write regular definitions for the following languages:

  • All strings of digits with no repeated digits. Hint: Try this problem first with a few digits, such as { 0, 1, 2 }.

Despite having tried to solve it for hours, I can't imagine a solution, beside the extremely wordy

d0 -> 0?
d1 -> 1?
d2 -> 2?
d3 -> 3?
d4 -> 4?
d5 -> 5?
d6 -> 6?
d7 -> 7?
d8 -> 8?
d9 -> 9?
d10 -> d0d1d2d3d4d5d6d7d8d9 | d0d1d2d3d4d5d6d7d9d8 | ...

Hence having to write 10! alternatives in d10. Since we shall write this regular definition, I doubt that this is a proper solution. Can you help me please?

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migrated from programmers.stackexchange.com Sep 25 '11 at 18:21

This question came from our site for professional programmers interested in conceptual questions about software development.

A disccussion of a similar question is at: perlmonks.org/?node_id=353072 – Emmad Kareem Sep 24 '11 at 14:27
Perhaps using call backs would help? – Jim Jeffries Sep 24 '11 at 17:17
Maybe the author is trying to show you that a regular expression isn't always the most compact representation? A finite state machine to do this would be pretty compact. It is fairly easy to show this is a regular language but that doesn't mean it has a short representation as a regular expression... As others noted if the complement operator is allowed things change. Wikipedia has a good discussion under Regular Expression. – Guy Sirton Sep 25 '11 at 3:49
Actually maybe there's no compact FSM either. The problem is there is a lot of state to capture all combinations of digits seen so far. – Guy Sirton Sep 25 '11 at 4:05
It's not clear to me whether "no repeated digits" means "no instances of two consecutive digits which are the same" or "no digit may appear twice anywhere in the string". Does the book provide any clues to disambiguate? – Peter Taylor Sep 25 '11 at 6:57
up vote 9 down vote accepted

So the question didn't necessarily ask you to write a regular expression, it asked you to provide a regular definition, which I interpret to include NFA's. It turns out it doesn't matter which you use, as all NFA's can be shown to be mathematically equivalent to regular expressions.

Using the digits 0, 1, and 2, a valid NFA would be the following (sorry for the crummy diagram):

enter image description here

Each state represents the last digit scanned in the input, and there are no loops on any of the nodes, therefore this is an accurate representation of a string with no repeated digits from the set {0,1,2}. Extending this is trivial (although it requires a large whiteboard :) ).

NOTE: I am making the assumption that the string "0102" IS valid, but the string "0012" is not.

This can be converted to a regular expression (although it will be painful) by using the algorithm described here.

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It's not hard to translate to a modern regex, especially if you're targeting an engine that supports backreferences in negative lookahead assertions (i.e., a recursive engine, such as PCRE). An RE like ^(?:(?!([0-2])\1).)*$ would seem appropriate (or failing that, expanding the possibilities for negative lookahead patterns). Without negative lookaheads, the regexp will be very painful, especially with larger alphabets… – Donal Fellows Sep 25 '11 at 21:09
@DonalFellows, we cannot use a negative lookahead (just look at the downvoted answer). Most lexical analyzers deal with regular expressions in a very theoretical sense. – Stargazer712 Sep 25 '11 at 21:16
I am probably doing something wrong, but when I used the procedure described in the PDF, the resulting regular expression does not appear to match the strings 01, 02, 012, 020, 021, 0101, and others. It appears to match any infinite string of {0, 1, 2} having non-consecutive-repeating digits, but not all finite-length strings meeting the same criterion. – Daniel Trebbien Sep 25 '11 at 21:30
That's why I did it as a comment on a correct (and attractive) answer (I like the diagram; makes it clear). I just felt that it is useful to provide a perspective on how this would be written as a regexp (distinguishing that from classical “regular expressions” though). – Donal Fellows Sep 25 '11 at 21:47
Sorry for the nitpick but the way Johannes is asking the question he is clearly trying to answer the question where 0102 is not valid given his sample solution. So basically we're telling him he's asked the wrong question and instead we're answering a trivial question? – Guy Sirton Sep 26 '11 at 22:21

Here's one possible construction:

  • A regex for a string that contains at the most a single '0' digit looks like (1-9)* (0|epsilon) (1-9)* - so any number of 1-9 digits, followed by zero or 1 '0's followed by any number of 1-9 digits.
  • We can now move forward by noticing that if there's only a single '1' digit it will be either to the left or to the right of the '0' digit (or the epsilon representing the missing zero digit). So we can construct a regular expression having these two cases or'ed (|) together.
  • We can now drill further down saying that if there's only a single '2' digit it can be to the right or the left of the 1 digit in it's two possible relative locations to the '0' digit.
  • So we're building a binary tree and the number of ORed regex is on the order of 2^10 which is the same order of the FSM accepting this language. An FSM for accepting the language should have (2^10 + 1) states with each state n can be seen as it's binary representation n0n1n2n3n4n5n6n7n8n9 meaning n0 = seen digit '0', n1 = seen digit '1'. and a repeat digit transitioning to the single non-accepting state. The initial state being zero.

If you're allowed to complement then a regex that has more than a single '0' digit would be (0-9)* 0 (0-9)* 0 (0-9)*, repeat for all digits, complement.

You can definitely be a lot more compact for Peter Taylors interpretation of no two consecutive digits that are the same. Clearly the state for that problem is much smaller.


"A study in [2] reveals that most of the one-unambiguous regular expression used in practice take a very simple form: every alphabet symbol occurs at most once. We refer to those as single-occurrence regular expressions (SOREs) and show a tight exponential lower bound for intersection."


"In this section, we show that in defining the complement of a single regular expression, a double-exponential size increase cannot be avoided in general. In contrast, when the expression is one-unambiguous its complement can be computed in polynomial time."

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Instead of trying to write a definition that only defines what you want, what if you tell it to generate a list of all strings up digits up to 10 digits in length, including duplicates, and then subtract the ones that contain two zeros, two ones... etc.? Would that work?

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(I don't know which variant of regular expressions you are referring to, if any, thus I will provide hints for the most general form of regular expressions.)

I find it a rather odd application of regular expressions since this is exactly one of the cases where they don't really provide a big benefit over other (more trivial to understand) solutions.

However, if you absolutely want to use regex, here's a hint (no solution since it's an exercise, let me know if you need more hints):

Regex allows you to recognize regular languages, which are generally accepted by deterministic finite state machines. Try to find a state machine which accepts exactly the words in the specified pattern. It'll require 2^10 = 1024 states but not 10! = 3628800.

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I don't have only 10! patterns. I have 10! alternatives in d10. If I replace d0, d1, ..., d9 in d10 by their respective right hand sides, I will have much more patterns, because each of those dX have two alternatives on their own (X|epsilon). Can you please show a string that is not matched by my naive definition? – Johannes Schaub - litb Sep 24 '11 at 14:46
BTW thanks for your hint I will investigate! – Johannes Schaub - litb Sep 24 '11 at 15:07
@JohannesSchaub-litb: Nevermind, I made a mistake in parsing your expression. Your solution is correct, but (as you recognized) overly verbose. – blubb Sep 25 '11 at 14:43

A regular definition is a sequence of definitions on the form

d1 -> r1

d2 -> r2


dn -> rn

Now make the following definitions:

Zero -> 0

One -> Zero (1 Zero)* | (Zero 1)+ | 1 (Zero 1)* | (1 Zero)+

Two -> One (2 One)* | (One 2)+ | 2 (One 2)* | (2 One)+

Three -> Two (3 Two)* | (Two 3)+ | 3 (Two 3)* | (3 Two)+

Four -> Three (4 Three)* | (Three 4)+ | 4 (Three 4)* | (4 Three)+


Nine -> Eight (9 Eight)* | (Eight 9)+ | 9 (Eight 9)* | (9 Eight)+

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I remember from my course of theoretical computer science: If a language L is regular, so is (not L), i.e., the language that contains all words not in L. -- Does this fit into the context of the exercise?

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It's easy to write a regex for the complement here but I don't think it helps us. – Guy Sirton Sep 25 '11 at 3:44
@Guy Sirton: It depends on the regex dialect. – krlmlr Sep 25 '11 at 6:31

Not sure what you mean by "Regular Expression" in your question title. But if the regex engine supports negative lookahead, this is easily accomplished. (Here's a PHP snippet)

$re = '/# Match string of digits having no repeated digits.
    ^                 # Anchor to start of string.
    (?![^0]*0[^0]*0)  # Assert 0 does not occur twice.
    (?![^1]*1[^1]*1)  # Assert 1 does not occur twice.
    (?![^2]*2[^2]*2)  # Assert 2 does not occur twice.
    (?![^3]*3[^3]*3)  # Assert 3 does not occur twice.
    (?![^4]*4[^4]*4)  # Assert 4 does not occur twice.
    (?![^5]*5[^5]*5)  # Assert 5 does not occur twice.
    (?![^6]*6[^6]*6)  # Assert 6 does not occur twice.
    (?![^7]*7[^7]*7)  # Assert 7 does not occur twice.
    (?![^8]*8[^8]*8)  # Assert 8 does not occur twice.
    (?![^9]*9[^9]*9)  # Assert 9 does not occur twice.
    [0-9]+            # Match string of only digits.
    $                 # Anchor to end of string.
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He's looking at the term "regular expression" in the sense of being equivalent to a "regular language". Negative lookaheads are definitely NOT a part of that definition. – Stargazer712 Sep 25 '11 at 20:15

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