First of all: brilliant question. I think it can be very instructive to try to take regex engines to their limits.
The basic .NET solution
You guys said in the comments that it would be easy with .NET, but since there is no answer for that yet, I thought I'd write one.
You can solve both question 1. and 2. using .NET's variablelength lookbehind and balancing groups. Most of the work is done by the balancing groups, but the variablelength lookbehind is crucial to be able to detected multiple matches starting on the same line.
Anyway, here is the pattern:
(?<= # lookbehind counts position of X into stack
^(?:(?<a>).)* # push an empty capture on the 'a' stack for each character
# in front of X
) # end of lookbehind
X # match X
(?=.*\n # lookahead checks that there are two more Xs right below
(?:(?<a>)(?<b>).)* # while we can pop an element from stack 'a', push an
# element onto 'b' and consume a character
(?(a)(?!)) # make sure that stack 'a' is empty
X.*\n # match X and the rest of the line
(?:(?<b>).)* # while we can pop an element from stack 'b', and consume
# a character
(?(b)(?!)) # make sure that stack 'b' is empty
X # match a final X
) # end of lookahead
This pattern has to be used with RegexOptions.Multiline
for the ^
to match the beginnings of lines (and obviously with RegexOptions.IgnorePatternWhitespace
for freespacing mode to work).
Here are some additional comments:
By putting everything except the initial X into lookarounds, we have no problems with overlapping matches or even matches starting on the same line. However, the lookbehind has to be of variablelength which certainly constrains any solution of this kind to .NET.
The rest relies on a good grasp on balancing groups. I won't go into this in detail here, because it makes for quite long answers in itself. (see MSDN and this blog post for even more information)
The lookbehind just matches ^.*
, so everything until the start of the line, but for every .
we push an empty capture onto stack a
, thereby counting the position of our X
as the size of the stack.
Then after consuming the rest of the line in the lookahead, we match again just .*
, but before consuming each .
, we pop one element from stack a
(which leads to failure, once a
is empty) and push an empty capture onto b
(so that we don't forget how many characters there have to be for the third line).
To make sure that we really empty the entire stack, we use (?(a)(?!))
. This is a conditional pattern, that tries to match (?!)
if stack a
is not empty (and is simply skipped otherwise). And (?!)
is an empty negative lookahead, which always fails. Hence, this simply encodes, "is a
not empty? fail. otherwise, continue".
Now that know we've consumed exactly the right amount of characters in the new line, we try to match a X
and the rest of the line. Then we repeat the same process again with stack b
. Now there is no need to push onto any new stack, because if this works, we're done. We check that b
is empty after this, and match a third X
.
Finally, an optimization side note: this pattern still works if all repetitions are wrapped in atomic groups (thereby emulating possessive quantifiers, which are not supported by .NET)! This would save a lot of backtracking. Moreover, if we put at least the stackpopping quantifiers in atomic groups, we can get rid of both (?(...)(?!))
checks (as these are only needed for cases, where the preceding repetition had to backtrack).
The full .NET solution
(Only the bravest of adventurers should follow me into the really dark cave I'm about to descend into...)
As discussed in the comments, this solution has one drawback: it counts overlapping matches. E.g.
..X..
..X..
..X..
..X..
Gives two matches, one in the first and one in the second line. We'd like to avoid this, and report only one match (or two if there are 6 to 8 X
s and three if there are 9 to 11 X
s and so on). Moreover, we want to report the matches at the 1st, 4th, 7th, ... X
.
We can adjust the above pattern to allow for this solution by requiring that the first X
is preceded by an integer multiple of 3 other X
s that statisfy our requirements. The basic idea of checking this uses the same stack manipulation as before (except we shift things around between 3 stacks so that after finding three X
s we end up where we started). To do this we have to fiddle a bit with the lookbehind.
There is a catch though. .NET's variablelength lookbehind uses another .NETunique feature, RightToLeftMode
, in which the pattern is read (and matched) from right to left. Normally this doesn't need to bother us, but when we combine this with balancing groups, we might be in for some unpleasant surprises. In particular, when considering how our capture stacks evolve, we need to construct (and read) the expression from right to left (or bottom to top) as well.
So when you read the following expression (and my annotations), start at the end of the outermost lookbehind (you'll have to scroll a bit)  i.e. just before the only toplevel X
; then read all the way up to the top. And then continue after the lookbehind.
(?<=
# note that the lookbehind below does NOT affect the state of stack 'a'!
# in fact, negative lookarounds can never change any capturing state.
# this is because they have to fail for the engine to continue matching.
# and if they fail, the engine needs to backtrack out of them, in which
# case the previous capturing state will be restored.
(?<! # if we get here, there is another X on top of the last
# one in the loop, and the pattern fails
^ # make sure we reached the beginning of the line
(?(a)(?!)) # make sure that stack 'a' is empty
(?:(?<a>).)* # while we can pop an element from stack 'a', and consume
# a character
X.*\n # consume the next line and a potential X
)
# at this point we know that there are less than 3 Xs in the same column
# above this position. but there might still be one or two more. these
# are the cases we now have to eliminate, and we use a nested negative
# lookbehind for this. the lookbehind simply checks the next row and
# asserts that there is no further X in the same column.
# this, together with the loop, below means that the X we are going to match
# is either the topmost in its column or preceded by an integer multiple of 3
# Xs  exactly what we are looking for.
(?:
# at this point we've advanced the lookbehind's "cursor" by exactly 3 Xs
# in the same column, AND we've restored the same amount of captures on
# stack 'a', so we're left in exactly the same state as before and can
# potentially match another 3 Xs upwards this way.
# the fact that stack 'a' is unaffected by a full iteration of this loop is
# also crucial for the later (lookahead) part to work regardless of the
# amount of Xs we've looked at here.
^ # make sure we reached the beginning of the line
(?(c)(?!)) # make sure that stack 'a' is empty
(?:(?<c>)(?<a>).)* # while we can pop an element from stack 'c', push an
# element onto 'a' and consume a character
X.*\n # consume the next line and a potential X
(?(b)(?!)) # make sure that stack 'b' is empty
(?:(?<b>)(?<c>).)* # while we can pop an element from stack 'b', push an
# element onto 'c' and consume a character
X.*\n # consume the next line and a potential X
(?(a)(?!)) # make sure that stack 'a' is empty
(?:(?<a>)(?<b>).)* # while we can pop an element from stack 'a', push an
# element onto 'b' and consume a character
X.*\n # consume the next line and a potential X
)* # this noncapturing group will match exactly 3 leading
# Xs in the same column. we repeat this group 0 or more
# times to match an integermultiple of 3 occurrences.
^ # make sure we reached the beginning of the line
(?:(?<a>).)* # push an empty capture on the 'a' stack for each
# character in front of X
) # end of lookbehind (or rather beginning)
# the rest is the same as before
X # match X
(?=.*\n # lookahead checks that there are two more Xs right below
(?:(?<a>)(?<b>).)* # while we can pop an element from stack 'a', push an
# element onto 'b' and consume a character
(?(a)(?!)) # make sure that stack 'a' is empty
X.*\n # match X and the rest of the line
(?:(?<b>).)* # while we can pop an element from stack 'b', and consume
# a character
(?(b)(?!)) # make sure that stack 'b' is empty
X # match a final X
) # end of lookahead
Working demo on RegexHero.net.
I interspersed all explanation right with the pattern this time. So if you read the pattern in the way I recommended above, you get the explanation right when you need it...
Now that was one hell of a beast. But it satisfies the entire specification now and shows off just how powerful .NET's regex flavor really is. And, although this seems quite horrible, I think (once you realise the righttoleftthing) this is much more easily understandable than a comparable solution with PCRE (using recursion or otherwise).
As Kobi mentioned in a comment below, this could be shortened a good bit, if you accept that your results are found in multiple captures of a single match (e.g., if you have a column of 7 X
s you only get one match, but with 2 captures in a certain group). You can do this by repeating the main (lookahead) part 1 or more times and capturing the initial X
(put everything in a lookahead though). Then the lookbehind does not need to count off triples of X
s, but only has to check that there is no leading X
. This would probably cut the size of the pattern in half.
The partial PCRE solution
(If only the bravest of adventurers followed me through the last solution, I am probably only left with madmen on the next journey...)
To prove what I just said about how the above solution compares to PCRE, let's look at how we can even remotely solve the full problem in PCRE. We'll have to work a good bit harder without variablelength lookbehinds and balancing groups.
Qtax (the OP) provided a brilliant solution to his first question (checking whether the string contains any X
column) using selfreferencing groups to count. This is a very elegant and compact solution. But because each match goes from the beginning of the line to the X
that starts the column, and matches cannot overlap, we can't get multiple matches per line. We could try to put everything in a lookahead (so that nothing is actually matched), but two zerowidth matches will also never start at the same position  so we'll still get only one match per candidate line.
However it is indeed possible to solve at least the first part of question 2 with PCRE: count the number of columns starting in each line (and hence to total amount of X
columns). Since we cannot get this count in the form of individual matches (see previous paragraph), and we cannot get this count in the form of individual groups or captures (since PCRE provides only a fixed and finite number of captures, as opposed to .NET). What we can do instead is to encode the number of columns in the matches.
Here is how: for each line we check if there's a column starting. If so, we include one character in a certain capturing group. Then, before reporting a successful match, we try to find as many further columns as possible  for each one adding a character to that particular group. By doing this, we encode the number of columns starting in each line in the length of that particular capture.
Actually realizing this concept in a regex is a lot more complicated than it may first sound (and it already sounds quite complicated). Anyway, here it is:
^
(?:(?
(?(5)(?![\s\S]*+\5))
(?!(?!)()())
(?=
(?:
.
(?=
.*+\n
( \3? . )
.*+\n
( \4? . )
)
)*?
X .*+\n
\3
X .*+\n
\4
)
()

(?(5)(?=[\s\S]*+\5)(?!))
(?:
.
(?=
.*+\n
( \1? .)
.*+\n
( \2? .)
)
)+?
(?=
(?<=X).*+\n
(\1)
(?<=X).*+\n
(\2)
(?<=X)
)
(?=
([\s\S])
[\s\S]*
([\s\S] (?(6)\6))
)
){2})+
(Actually, it's a bit easier than that  see Qtax's answer for how to simplify this approach. I'll leave this approach here anyway for academic reasons, as some very advanced and interesting techniques can be learned from it  see the summary at the end.)
Yes, there are no annotations. I figured, no one would actually read them anyway, so instead I'll try to break this expression down in parts (I'll go for a topdown approach).
So let's look at the outer layer of onion from hell:
^
(?:(?
checkForNextColumn

countAndAdvance
){2})+
So our matches are again anchored to the beginnings of lines. Then we have a (?:...{2})+
which means an even number of repetitions of something. And that something is an alternation of two subpatterns. These subpatterns represent the steps I mentioned above. The first one checks that there is another column starting in the current line, the second one registers a count and prepares the engine's state for another application of the first subpattern. So control is given to the second pattern  the first just checks for another column using a lookahead and is hence a zerowidth pattern. This is why I cannot simply wrap everything in +
but have to do the {2})+
thing  otherwise the zerowidth component would be tried only once; that's a necessary optimization applied by pretty much all engines to avoid infinite loops with patterns like (a*)+
.
There is one more (very important detail): I used (?...)
for the alternation. In this kind of grouping, each alternative starts with the same group number. Hence in /(?(a)(b))/
both a
and b
can be captured into group 1
. This is the crucial trick that allows "communication" between subpatterns, as they can modify the same groups.
Anyway... so we have these two subpatterns. We'd like to make sure that control really alternates between them. So that each group fails if it was the last one that matched. We do this by wrapping the pattern in some groupingandreferencing magic:
^(?:(?
(?(5)(?![\s\S]*+\5)) # if group 5 has matched before make sure that
# it didn't match empty
checkForNextColumn # contains 4 capturing groups
() # this is group 5, match empty

(?(5)(?=[\s\S]*+\5)(?!)) # make sure that group 5 is defined and that it
# matched empty
advanceEngineState # contains 4 capturing groups
(?=
([\s\S]) # this is group 5, match nonempty
[\s\S]* # advance to the end very end of the string
([\s\S] (?(6)\6)) # add a character from the end of the string to
# group 6
)
){2})+
So at the end of each alternative, we'll invalidate the condition for this alternative to even start matching. At the end of the second alternative we'll also include a character into group 6
, using the technique outlined by Qtax. This is the counting step. I.e., group 6
will contain as many characters as there are columns starting in the current line.
Now checkForNextColumn
will really just be Qtax's solution inside a lookahead. It needs one more modification though and to justify this we'll look into advanceEngineState
first.
Let's think about how we would want to modify the state, for Qtax's solution to match a second column in a row. Say we have input
..X..X..
..X..X..
..X..X..
and we want to find the second column. This could be accomplished, by starting the match from the position just after the first X
and having groups \1
and \2
already initialised to the first three characters (..X
) of rows 2 and 3, respectively (instead of them being empty).
Now let's try to do this: match everything up to and including the next X
that starts a column, then fill two groups with the corresponding lineprefixes for use in the checkForNextColumn
pattern. This is again pretty much Qtax's pattern, except that we count the X
in (instead of stopping right before it), and that we need to add the capturing into a separate group. So here is advanceEngineState
:
(?:
.
(?=
.*+\n
( \1? .)
.*+\n
( \2? .)
)
)+?
(?=
(?<=X) .*+\n
(\1)
(?<=X) .*+\n
(\2)
(?<=X)
)
Note how I turned the X
s into lookbehinds, to go one character further, and how I effectively copy the final contents of \1
into \3
and those of \2
into \4
.
So if we now use Qtax's solution as checkForNextColumn
in a lookahead, using groups \3
and \4
instead of \1
and \2
, we should be done.
But just how do we make those groups \3
and \4
instead of \1
and \2
? We could start the pattern with ()()
, which would always match, without affecting the engine's cursor, but increase the group count by 2. However, this is problematic: this resets groups 1
and 2
to empty strings, which if we find a second column, advanceEngineState
will be in an inconsistent state (as the engine's global position has been advanced, but the counting groups are zero again). So we want to get those two groups into the pattern, but without affecting what they are currently capturing. We can do this by utilizing something I already mentioned with the .NET solutions: groups in negative lookarounds do not affect the captured contents (because the engine needs to backtrack out of the lookaround to proceed). Hence we can use (?!(?!)()())
(a negative lookahead that can never cause the pattern to fail) to include two sets of parentheses in our pattern, that are never used. This allows us to work with groups 3
and 4
in our first subpattern, while keeping groups 1
and 2
untouched for the second subpatterns next iteration. In conclusion this is checkForNextColumn
:
(?!(?!)()())
(?=
(?:
.
(?=
.*+\n
( \3? . )
.*+\n
( \4? . )
)
)*?
X .*+\n
\3
X .*+\n
\4
)
Which, for the most part actually looks really familiar.
So this is it. Running this against some input will give us a group 6
which contains one capture for each line that has a column starting  and the capture's length will tell us how many columns started there.
Yes, it really works (live demo).
Note that this (like the basic .NET solution) will overcount columns that are more than 3 X
s long. I suppose it is possible to correct this count with lookaheads (in a similar way to the lookbehind of the full .NET solution), but this is left as an exercise to the reader.
It's a bit unfortunate that the base problem of this solution is already very convoluted and bloats the solution (75% of the lines are mostly just copies of Qtax's solution). Because the surrounding framework has some really interesting techniques and lessons:
 We can have multiple subpatterns that accomplish specific matching/counting tasks, and have them "communicate" through mutual capturing groups, by putting them in a
(?...)
alternation and looping over them.
 We can force zerowidth alternatives to be carried out over and over again by wrapping them in a finite quantifier like
{2}
before putting everything into +
.
 Group numbers can be skipped in one subpattern (without affecting the captured contents) by putting them into a neverfailing negative lookahead like
(?!(?!)())
.
 Control can be passed back and forth between subpatterns by capturing something or nothing in a certain group that is checked upon entering the alternation.
This allows for some very powerful computations (I've seen claims that PCRE is in fact Turingcomplete)  although this is certainly the wrong approach for productive use. But still trying to understand (and come up) with such solutions can be a very challenging and somehow rewarding exercise in problem solving.
XXXX
count as 0, 1 or 2 sequences of 3X
s?