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I can't figure out how to construct a regex for the example values:

123,456,789
-12,34
1234
-8

Could you help me?

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2  
Is "-12,34" considered valid? In everyday usage it is not and makes a HUGE difference on the resulting regex. –  Jason Nov 22 '10 at 13:57
9  
',' == nutty European '.' –  Andrew Nov 22 '10 at 14:08
1  
@user278618, if you edit your profile, you can change your name from user278618 to anything you please. –  tchrist Nov 23 '10 at 11:28
    
@user278618 please see my updated answer. I’ve explained all the mysterious patterns I suggested, cited the source material where I got it all from, and then showed several substantial improvements, first with white space and comments, then with named groups, and finally with a fully grammatical patterns. Check it out! –  tchrist Nov 23 '10 at 14:41
1  
Jason: not everyone uses . for separating integral and fractional part ... –  Јοеу Apr 20 '12 at 5:51
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10 Answers

up vote 26 down vote accepted

If you only want to allow digits and commas, ^[-,0-9]+$ is your regex. If you also want to allow spaces, use ^[-,0-9 ]+$.

However, if you want to allow proper numbers, better go with something like this:

^([-+] ?)?[0-9]+(,[0-9]+)?$

or simply use .net's number parser (for the various NumberStyles, see MSDN):

try {
    double.Parse(yourString, NumberStyle.Number);
}
catch(FormatException ex) {
    /* Number is not in an accepted format */
}
share|improve this answer
    
Also allws ,,,,1,,,,2,,, –  Paul Nov 22 '10 at 13:59
1  
Yep, see my addition - his question didn't mention if he wants to allow "only digits and commas" or if he wants to check for valid numbers. –  ThiefMaster Nov 22 '10 at 14:00
2  
that’s pretty nasty. I don’t think it even answers his question. Then again, the question which @user278618 asked does not line up with the examples which @user278618 provided. I gave many solutions in my own answer, none of which have any of the many, many problems that yours has. It is possible that my /^(?:(?:[+-]?)(?:[0123456789]{1,3}(?:,?[0123456789]{3})*))$/ will satisfy his needs, but it is impossible to tell because of the imprecise and conflictive wording. But certainly mine does a much better job than yours does! –  tchrist Nov 22 '10 at 20:05
    
I could just guess what exactly he wanted as his question was very unclear. –  ThiefMaster Nov 22 '10 at 20:57
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up vote 359 down vote
+200

What’s a Number?

I have a simple question for your “simple” question: What precisely do you mean by “a number”?

  • Is −0 a number?
  • How do you feel about √−1?
  • Is or a number?
  • Is 186,282.42±0.02 miles/second one number — or is it two or three of them?
  • Is 6.02e23 a number?
  • Is 3.141_592_653_589 a number? How about π, or ? And −2π⁻³ ͥ?
  • How many numbers in 0.083̄?
  • How many numbers in 128.0.0.1?
  • What number does hold? How about ⚂⚃?
  • Does 10,5 mm have one number in it — or does it have two?
  • Is ∛8³ a number — or is it three of them?
  • What number does ↀↀⅮⅭⅭⅬⅫ AUC represent, 2762 or 2009?
  • Are ४५६७ and ৭৮৯৮ numbers?
  • What about 0377, 0xDEADBEEF, and 0b111101101?
  • Is Inf a number? Is NaN?
  • Is ④② a number? What about ?
  • How do you feel about ?
  • What do ℵ₀ and ℵ₁ have to do with numbers? Or , , and ?

Suggested Patterns

Also, are you familiar with these patterns? Can you explain the pros and cons of each?

  1. /\D/
  2. /^\d+$/
  3. /^\p{Nd}+$/
  4. /^\pN+$/
  5. /^\p{Numeric_Value:10}$/
  6. /^\P{Numeric_Value:NaN}+$/
  7. /^-?\d+$/
  8. /^[+-]?\d+$/
  9. /^-?\d+\.?\d*$/
  10. /^-?(?:\d+(?:\.\d*)?|\.\d+)$/
  11. /^([+-]?)(?=\d|\.\d)\d*(\.\d*)?([Ee]([+-]?\d+))?$/
  12. /^((\d)(?(?=(\d))|$)(?(?{ord$3==1+ord$2})(?1)|$))$/
  13. /^(?:(?:25[0-5]|2[0-4][0-9]|[0-1]?[0-9]{1,2})[.](?:25[0-5]|2[0-4][0-9]|[0-1]?[0-9]{1,2})[.](?:25[0-5]|2[0-4][0-9]|[0-1]?[0-9]{1,2})[.](?:25[0-5]|2[0-4][0-9]|[0-1]?[0-9]{1,2}))$/
  14. /^(?:(?:[0-9a-fA-F]{1,2}):(?:[0-9a-fA-F]{1,2}):(?:[0-9a-fA-F]{1,2}):(?:[0-9a-fA-F]{1,2}):(?:[0-9a-fA-F]{1,2}):(?:[0-9a-fA-F]{1,2}))$/
  15. /^(?:(?:[+-]?)(?:[0123456789]+))$/
  16. /(([+-]?)([0123456789]{1,3}(?:,?[0123456789]{3})*))/
  17. /^(?:(?:[+-]?)(?:[0123456789]{1,3}(?:,?[0123456789]{3})*))$/
  18. /^(?:(?i)(?:[+-]?)(?:(?=[0123456789]|[.])(?:[0123456789]*)(?:(?:[.])(?:[0123456789]{0,}))?)(?:(?:[E])(?:(?:[+-]?)(?:[0123456789]+))|))$/
  19. /^(?:(?i)(?:[+-]?)(?:(?=[01]|[.])(?:[01]{1,3}(?:(?:[,])[01]{3})*)(?:(?:[.])(?:[01]{0,}))?)(?:(?:[E])(?:(?:[+-]?)(?:[01]+))|))$/
  20. /^(?:(?i)(?:[+-]?)(?:(?=[0123456789ABCDEF]|[.])(?:[0123456789ABCDEF]{1,3}(?:(?:[,])[0123456789ABCDEF]{3})*)(?:(?:[.])(?:[0123456789ABCDEF]{0,}))?)(?:(?:[G])(?:(?:[+-]?)(?:[0123456789ABCDEF]+))|))$/
  21. /((?i)([+-]?)((?=[0123456789]|[.])([0123456789]{1,3}(?:(?:[_,]?)[0123456789]{3})*)(?:([.])([0123456789]{0,}))?)(?:([E])(([+-]?)([0123456789]+))|))/

I suspect that some of those patterns above may serve your needs. But I cannot tell you which one or ones — or, if none, supply you another — because you haven’t said what you mean by “number”.

As you see, there are a huge number of number possibilities: quite probably ℵ₁ worth of them, in fact. ☺

Key to Suggested Patterns

Each numbered explanation before describes the pattern of that particular pattern listed above.

  1. Match if there are any non-digits anywhere in the string, including whitespace like linebreaks.
  2. Match only if the string contains nothing but digits, with the possible exception of a trailing linebreak. Note that a digit is defined as having the property General Category Decimal Number, which is available as \p{Nd}, \p{Decimal_Number}, or \p{General_Category=Decimal_Number}. This is turn is actually just a reflection of those code points whose Numeric Type category is Decimal, which is available as \p{Numeric_Type=Decimal}.
  3. This is the same as 2 in most regex languages. Java is an exception here, because it does not map the simple charclass escapes like \w and \W, \d and \D, \s and \S, and \b or \B into the appropriate Unicode property. That means you must not use any of those eight one-character escapes for any Unicode data in Java, because they work only on ASCII even though Java always uses Unicode characters internally.
  4. This is slightly different from 3 in that it isn’t limited to decimal numbers, but can be any number at all; that is, any character with the \pN, \p{Number}, or \p{General_Category=Number} property. These include \p{Nl} or \p{Letter_Number} for things like Roman numerals and \p{No} or \p{Other_Number} for subscripted and subscripted numbers, fractions, and circled numbers — amongst others, like counting rods.
  5. This matches only those strings composed entirely of numbers whose decimal value is 10, so things like the Roman numeral ten, and , , , , , , and .
  6. Only those strings that contain characters that lack the Numeric Value NaN; in other words, all chars must have some numeric value.
  7. Matches only Decimal Numbers, optionally with a leading HYPHEN MINUS.
  8. Same as 7 but now also works if the sign is plus instead of minus.
  9. Looks for decimal numbers, with optional HYPHEN MINUS and optional FULL STOP plus zero or more decimal numbers following.
  10. Same as 9 but doesn’t require digits before the dot if it has some afterwords.
  11. Standard floating-point notation per C and many other languages, allowing for scientific notation.
  12. Finds numbers composed only of two or more decimals of any script in descending order, like 987 or 54321. This recursive regex includes a callout to Perl code that checks whether the lookahead digit has a code point value that is the successor of the current digit; that is, its ordinal value is one greater. One could do this in PCRE using a C function as the callout.
  13. This looks for a valid IPv4 address with four decimal numbers in the valid range, like 128.0.0.1 or 255.255.255.240, but not 999.999.999.999.
  14. This looks for a valid MAC addr, so six colon-separate paris of two ASCII hex digits.
  15. This looks for whole numbers in the ASCII range with an optional leading sign. This is the normal pattern for matching ASCII integers.
  16. This is like 15, except that it requires a comma to separate groups of three.
  17. This is like 15, except that the comma for separating groups is now optional.
  18. This is the normal pattern for matching C-style floating-point numbers in ASCII.
  19. This is like 18, but requiring a comma to separate groups of 3 and in base-2 instead of in base-10.
  20. This is like 19, but in hex. Note that the optional exponent is now indigcated by a G instead of an E, since E is a valid hex digit.
  21. This checks that the string contains a C-style floating-point number, but with an optional grouping separator every three digits of either a comma or an underscore (LOW LINE) between them. It also stores that string into the \1 capture group, making available as $1 after the match succeeds.

Sources and Maintainability

Patterns number 1,2,7–11 come from a previous incarnation of the Perl Frequently Asked Questions list in the question, “How do I validate input?”. That section has been replaced by a suggestion to use the Regexp::Common module, written by Abigail and Damian Conway. The original patterns can still be found in Recipe 2.1 of the Perl Cookbook, “Checking Whether a String Is a Valid Number”, solutions to which can be found for a dizzying number of diverse languages, including ada, common lisp, groovy, guile, haskell, java, merd, ocaml, php, pike, python, rexx, ruby, and tcl at the the PLEAC project.

Pattern 12 could be more legibly rewritten

m{
    ^
    (
        ( \d )
        (?(?= ( \d ) ) | $ )
        (?(?{ ord $3 == 1 + ord $2 }) (?1) | $ )
    )
    $
}x

It uses regex recursion, which is found in many pattern engines, including Perl and all the PCRE-derived languages. But it also uses an embedded code callout as the test of its second conditional pattern; to my knowledge, code callouts are available only in Perl and PCRE.

Patterns 13–21 were derived from the aforementioned Regexp::Common module. Note that for brevity, these are all written without the whitespace and comments that you would definitely want in production code. Here is how that might look in /x mode:

$real_rx = qr{ (   # start $1 to hold entire pattern
    ( [+-]? )                  # optional leading sign, captured into $2
    (                          # start $3
        (?=                    # lookahead for what next char *will* be
            [0123456789]       #    EITHER:  an ASCII digit
          | [.]                #    OR ELSE: a dot
        )                      # end lookahead
        (                      # start $4
           [0123456789]{1,3}       # 1-3 ASCII digits to start the number
           (?:                     # then optionally followed by
               (?: [_,]? )         # an optional grouping separator of comma or underscore
               [0123456789]{3}     # followed by exactly three ASCII digits
           ) *                     # repeated any number of times
        )                          # end $4
        (?:                        # begin optional cluster
             ( [.] )               # required literal dot in $5
             ( [0123456789]{0,} )  # then optional ASCII digits in $6
        ) ?                        # end optional cluster
     )                         # end $3
    (?:                        # begin cluster group
        ( [E] )                #   base-10 exponent into $7
        (                      #   exponent number into $8
            ( [+-] ? )         #     optional sign for exponent into $9
            ( [0123456789] + ) #     one or more ASCII digits into $10
        )                      #   end $8
      |                        #   or else nothing at all
    )                          # end cluster group
) }xi;          # end $1 and whole pattern, enabling /x and /i modes

From a software engineering perspective, there are still several issues with the style used in the /x mode version immediately above. First, there is a great deal of code repetition, where you see the same [0123456789]; what happens if one of those sequences accidentally leaves a digit out? Second, you are relying on positional parameters, which you must count. That means you might write something like:

(
  $real_number,          # $1
  $real_number_sign,     # $2
  $pre_exponent_part,    # $3
  $pre_decimal_point,    # $4
  $decimal_point,        # $5
  $post_decimal_point,   # $6
  $exponent_indicator,   # $7
  $exponent_number,      # $8
  $exponent_sign,        # $9
  $exponent_digits,      # $10
) = ($string =~ /$real_rx/);

which is frankly abominable! It is easy to get the numbering wrong, hard to remember what symbolic names go where, and tedious to write, especially if you don’t need all those pieces. Rewriting that to used named groups instead of just numbered ones. Again, I’ll use Perl syntax for the variables, but the contents of the Pattern should work anywhere that named groups are supported.

use 5.010;              # Perl got named patterns in 5.10
$real_rx = qr{
  (?<real_number>
    # optional leading sign
    (?<real_number_sign> [+-]? )
    (?<pre_exponent_part>
        (?=                         # lookahead for what next char *will* be
            [0123456789]            #    EITHER:  an ASCII digit
          | [.]                     #    OR ELSE: a dot
        )                           # end lookahead
        (?<pre_decimal_point>
            [0123456789]{1,3}       # 1-3 ASCII digits to start the number
            (?:                     # then optionally followed by
                (?: [_,]? )         # an optional grouping separator of comma or underscore
                [0123456789]{3}     # followed by exactly three ASCII digits
            ) *                     # repeated any number of times
         )                          # end <pre_decimal_part>
         (?:                        # begin optional anon cluster
            (?<decimal_point> [.] ) # required literal dot
            (?<post_decimal_point>
                [0123456789]{0,}  )
         ) ?                        # end optional anon cluster
   )                                # end <pre_exponent_part>
   # begin anon cluster group:
   (?:
       (?<exponent_indicator> [E] ) #   base-10 exponent
       (?<exponent_number>          #   exponent number
           (?<exponent_sign>   [+-] ?         )
           (?<exponent_digits> [0123456789] + )
       )                      #   end <exponent_number>
     |                        #   or else nothing at all
   )                          # end anon cluster group
 )                            # end <real_number>
}xi;

Now the abstractions are named, which helps. You can pull the groups out by name, and you only need the ones you care about. For example:

if ($string =~ /$real_rx/) {
    ($pre_exponent, $exponent_number) =
        @+{ qw< pre_exponent exponent_number > };
}

There’s one more thing to do this pattern to make it stilll more maintainable. The problrm is that there’s still too much repetition, which means it’s too easily changed in one place but not in another. If you were doing a McCabe analysis, you would say its complexity metric is too high. Most of us would just say it’s too indented. This makes it hard to follow. To fix all these things, what we need is a “grammatical pattern”, one with a definition block to create named abstractions, which we then treat somewhat like a subroutine call later on in the match.

use 5.010;              # Perl first got regex subs in v5.10
$real__rx = qr{ 

    ^                   # anchor to front
    (?&real_number)     # call &real_number regex sub
    $                   # either at end or before final newline

  ##################################################
  # the rest is definition only; think of         ##
  # each named buffer as declaring a subroutine   ##
  # by that name                                  ##
  ##################################################
  (?(DEFINE)
      (?<real_number>
          (?&mantissa)
          (?&abscissa) ?

      )
      (?<abscissa>
          (?&exponent_indicator)
          (?&exponent)
      )
      (?<exponent>
          (&?sign)    ?
          (?&a_digit) +
      )
      (?<mantissa>
         # expecting either of these....
         (?= (?&a_digit)
           | (?&point)
         )
         (?&a_digit) {1,3}
         (?: (?&digit_separator) ?
             (?&a_digit) {3}
         ) *
         (?: (?&point)
             (?&a_digit) *
         ) ?
      )
      (?<point>               [.]     )
      (?<sign>                [+-]    )
      (?<digit_separator>     [_,]    )
      (?<exponent_indicator>  [Ee]    )
      (?<a_digit>             [0-9]   )
   ) # end DEFINE block
}x;

See how insanely better the grammatical pattern is than the original line-noisy pattern? It’s also far easier to get the syntax right: I typed that in without even one regex syntax error that needed correcting. (Ok fine, I typed all the others in without any syntax errors either, but I’ve been doing this for a while. :)

Grammatical patterns look much more like a BNF than the ugly old regular expressions that people have come to hate. They are far easier to read, write, and maintain. So let’s have no more ugly patterns, OK?

share|improve this answer
11  
Nice one, +1 as I had to smile about that answer. –  ThiefMaster Nov 23 '10 at 11:28
4  
@ThiefMaster, I hope that now with the elaborate explanation answering my original, quite non-rhetorical question, that you don’t just smile but indeed grin from ear to ear! :) –  tchrist Nov 23 '10 at 14:44
2  
Great answer - but you have 21 patterns and 20 explanations. :) –  Anthony Mills Apr 18 '12 at 21:05
2  
I have an excellent idea, let's have a debate whether there are ℵ₁ meaningful number regexps or only ℵ₀ of them. –  chx Apr 18 '12 at 21:08
7  
To see the universe in a grain of sand - regex, readability, framing the question, robustness, clarity, illumination - eternity in an hour - how much wisdom is compressed into this answer? –  Phil H Apr 19 '12 at 9:31
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Try this:

^-?\d{1,3}(,\d{3})*(\.\d\d)?$|^\.\d\d$

Allows for:

1
12
.99
12.34 
-18.34
12,345.67
999,999,999,999,999.99
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Try this:

^-?[\d\,]+$

It will allow an optional - as the first character, and then any combination of commas and digits.

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4  
Including ,,,1,,,2,,,, –  Paul Nov 22 '10 at 13:58
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Since this question has been reopened four years later, I'd like to offer a different take. As someone spends a lot of time working with regex, my view is this:

A. If Possible, Don't Use Regex To Validate Numbers

If at all possible, use your language. There may be functions to help you determine if the value contained by a string is a valid number. That being said, if you're accepting a variety of formats (commas, etc.) you may not have a choice.

B. Don't Write the Regex Manually to Validate a Number Range

  • Writing a regex to match a number in a given range is hard. You can make a mistake even writing a regex to match a number between 1 and 10.
  • Once you have a regex for a number range, it's hard to debug. First, it's awful to look at. Second, how can you be sure it matches all the values you want without matching any of the values you don't want? Frankly, if you're by yourself, without peers looking over your shoulder, you can't. The best debugging technique is to output a whole range of numbers programmatically and check them against the regex.
  • Fortunately, there are tools to generate a regex for a number range automatically.

C. Spend your Regex Energy Wisely: Use Tools

  • Matching numbers in a given range is a problem that has been solved. There's no need for you to try to reinvent the wheel. It's a problem that can be solved mechanically, by a program, in a way that is guaranteed to be error-free. Take advantage of that free ride.
  • Solving a number-range regex may be interesting for learning purposes a couple of times. Beyond that, if you have energy to invest in furthering your regex skills, spend it on something useful, such as deepening your understanding of regex greed, reading up on Unicode regex, playing with zero-width matches or recursion, reading the SO regex FAQ and discovering neat tricks such as how to exclude certain patterns from a regex match... or reading classics such as Matering Regular Expressions, 3rd Ed or The Regular Expressions Cookbook, 2nd Ed .

For tools, you can use:

  • Online: Regex_for_range
  • Offline: the only one I'm aware of is RegexMagic (not free) by regex guru Jan Goyvaerts. It's his beginner regex product, and as I recall it has a great range of options for generating numbers in a given range, among other features.
  • If the conditions are too complex, auto-generate two ranges... then join them with an alternation operator |

D. An Exercise: Building a Regex for the Specs in the Question

These specs are quite wide... but not necessarily vague. Let's look at the sample values again:

123,456,789
-12,34
1234
-8

How do the first two values relate? In the first, the comma matches groups of powers of three. In the second, it probably matches the decimal point in a continental-European-style number format. That does not mean we should allow digits everywhere, as in 1,2,3,44. By the same token, we shouldn't be restrictive. The regex in the accepted answer, for instance, will not match one of the requirements, 123,456,789 (see demo).

How do we build our regex to match the specs?

  • Let's anchor the expression between ^ and $ to avoid submatches
  • Let's allow an optional minus: -?
  • Let's match two types of numbers on either side of an alternation (?:this|that):
  • On the left, a European-style digit with optional comma for decimal part: [1-9][0-9]*(?:,[0-9]+)?
  • On the right, a number with thousands separators: [1-9][0-9]{1,2}(?:,[0-9]{3})+

The complete regex:

^-?(?:[1-9][0-9]*(?:,[0-9]+)?|[1-9][0-9]{1,2}(?:,[0-9]{3})+)$

See demo.

This regex does not allow European-style numbers starting with 0, such as 0,12. It's a feature, not a bug. To match those as well, a small tweak will do:

^-?(?:(?:0|[1-9][0-9]*)(?:,[0-9]+)?|[1-9][0-9]{1,2}(?:,[0-9]{3})+)$

See demo.

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^-?    # start of line, optional -
(\d+   # any number of digits
|(\d{1,3}(,\d{3})*))  # or digits followed by , and three digits
((,|\.)\d+)? # optional comma or period decimal point and more digits
$  # end of line
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In java, You may use java.util.Scanner with its useLocale method

Scanner myScanner =  new Scanner(input).useLocale( myLocale)

isADouble = myScanner.hasNextDouble()
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For the examples:

    ^(-)?([,0-9])+$

It should work. Implement it in whichever language you want.

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^[-+]?(\d{1,3})(,?(?1))*$

Regular expression visualization

Debuggex Demo

So what does it?!

  • ^ marks the beginning of the string
  • [-+]? allows a minus or plus right after the beginning of the string
  • (\d{1,3}) matches at least one and max three ({1,3}) digits (\d - commonly [0-9]) in a row and groups them (the parenthesises (...) builds the group) as the first group
  • (,?(?1))* ok... let's break this down
    • (...) builds another group (not so important)
    • ,? matches a comma (if existent) right after the first sequence of digits
    • (?1) matches the pattern of the first group again (remember (\d{1,3})); in words: at this point the expression matches a sign (plus/minus/none) followed by a sequence of digits possibly followed by a comma, followed by another sequence of digits again.
    • (,?(?1))*, the * repeats the second part (comma & sequence) as often as possible
  • $ finally matches the end of the string

the advantage of such expressions is, to avoid to define the same pattern within your expression again and again and again... well, a disadvantage is sometimes the complexity :-/

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Put all the whole regexes inside character class,

^[0-9\-,]+$

DEMO

Explanation:

  • ^ asserts to the starting point.

  • [0-9\-,]+ Matches a number from 0-9 or - or , one or more times.

  • $ End of the string

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you need to escape the - character when you mean it literally; eg: \-. Inside a character class, -,, [, and ] are the only meta-characters that need to be escaped. –  ThorSummoner Jun 28 at 18:24
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