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I'm trying to split up a string into two parts using regex. The string is formatted as follows:

text to extract<number>

I've been using (.*?)< and <(.*?)> which work fine but after reading into regex a little, I've just started to wonder why I need the ? in the expressions. I've only done it like that after finding them through this site so I'm not exactly sure what the difference is.

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see also… – Cemafor Jul 19 '13 at 19:30
up vote 33 down vote accepted

It is the difference between greedy and non-greedy.

consider the input 101000000000100

using 1.*1, * is greedy - it will match all the way to the end, and then backtrack until it can match 1, leaving you with 1010000000001.
.*? is non-greedy. * will match nothing, but then try to match extra characters until it matches 1, eventually matching 101.

All quantifiers have a non-greedy mode: .*?, .+?, .{2,6}?, and even .??.

In your case, a similar patters could be <([^>]*)> - matching anything besides a greater-than sign.

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Ah great I like that last one of anything but the > sign! – DiGiTaLFX Jun 19 '10 at 13:58
Can you explain or show an example of how the greedy ? differs from the non-greedy ?? ? – AdrianHHH Nov 25 '15 at 15:36
Sure. For the string "abc", the regex /\w\w?\w/ would match the full string "abc" - because ? is greedy. /\w\w??\w/ is lazy - it will only match "ab". It will only backtrack and match "abc" if it fails later. – Kobi Nov 26 '15 at 16:34

Let's say you have:


<(.*)> would match a></a where as <(.*?)> would match a. The latter stops after the first match of >. It checks for one or 0 matches of .* followed by the next expression.

The first expression <(.*)> doesn't stop when matching the first >. It will continue until the last match of >.

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Thanks that clearly and concisely explains it :) – DiGiTaLFX Jun 19 '10 at 13:59

On greedy vs non-greedy

Repetition in regex by default is greedy: they try to match as many reps as possible, and when this doesn't work and they have to backtrack, they try to match one fewer rep at a time, until a match of the whole pattern is found. As a result, when a match finally happens, a greedy repetition would match as many reps as possible.

The ? as a repetition quantifier changes this behavior into non-greedy, also called reluctant (in e.g. Java) (and sometimes "lazy"). In contrast, this repetition will first try to match as few reps as possible, and when this doesn't work and they have to backtrack, they start matching one more rept a time. As a result, when a match finally happens, a reluctant repetition would match as few reps as possible.


Example 1: From A to Z

Let's compare these two patterns: A.*Z and A.*?Z.

Given the following input:


The patterns yield the following matches:

Let's first focus on what A.*Z does. When it matched the first A, the .*, being greedy, first tries to match as many . as possible.

    A.* matched, Z can't match

Since the Z doesn't match, the engine backtracks, and .* must then match one fewer .:

    A.* matched, Z still can't match

This happens a few more times, until finally we come to this:

    A.* matched, Z can now match

Now Z can match, so the overall pattern matches:

    A.*Z matched

By contrast, the reluctant repetition in A.*?Z first matches as few . as possible, and then taking more . as necessary. This explains why it finds two matches in the input.

Here's a visual representation of what the two patterns matched:

   \__/r   \___/r      r = reluctant
    \____g____/        g = greedy

Example: An alternative

In many applications, the two matches in the above input is what is desired, thus a reluctant .*? is used instead of the greedy .* to prevent overmatching. For this particular pattern, however, there is a better alternative, using negated character class.

The pattern A[^Z]*Z also finds the same two matches as the A.*?Z pattern for the above input (as seen on [^Z] is what is called a negated character class: it matches anything but Z.

The main difference between the two patterns is in performance: being more strict, the negated character class can only match one way for a given input. It doesn't matter if you use greedy or reluctant modifier for this pattern. In fact, in some flavors, you can do even better and use what is called possessive quantifier, which doesn't backtrack at all.


Example 2: From A to ZZ

This example should be illustrative: it shows how the greedy, reluctant, and negated character class patterns match differently given the same input.


These are the matches for the above input:

Here's a visual representation of what they matched:

        /   \              n = negated character class
eeAiiZooAuuZZeeeZZfff      r = reluctant
  \_________/r   /         g = greedy

Related topics

These are links to questions and answers on stackoverflow that cover some topics that may be of interest.

One greedy repetition can outgreed another

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I meant to say, not To others: don't revise this post for me, I'll do it myself on next revision, along with other examples. Feel free to give feedback, suggestion, etc in comments so I can incorporate those as well. – polygenelubricants Jun 19 '10 at 13:37
See also:… – polygenelubricants Jun 29 '10 at 21:57
Haha, nice cruise ship there on the last example :). Anyway - thank you a million. You explained everything just perfect. – Norris Oct 23 '11 at 17:45
Amazing explanation. thanks – Pradyot Sep 14 '12 at 14:54
This answer has been added to the Stack Overflow Regular Expression FAQ, under "Quantifiers > More on the differences..." – aliteralmind Apr 10 '14 at 0:09

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