643

When comparing two strings in c# for equality, what is the difference between InvariantCulture and Ordinal comparison?

5
  • Maybe siao2.com/2004/12/29/344136.aspx ? (googled) Jan 29, 2009 at 18:30
  • 2
    For those using String1.Equals(String2, StringComparison.Ordinal), you better use String1 == String2 which is intrinsically String1.Equals(String2) and it is by default an ordinal case-sensitive comparison. Nov 5, 2014 at 12:53
  • 3
    @Ghasan Not sure if that makes == "better", but it is a) shorter, b) less explicit about what exactly it does and c) String1 can be null without the comparison throwing a NullReferenceException. Jul 28, 2015 at 4:18
  • 3
    @Ghasan the official MSDN Best Practices for Using Strings in the .NET Framework page (msdn.microsoft.com/en-us/library/…) recommends the usage of overloads that explicitly specify the StringComparison type. In the case of string comparison, it means String.Equals. Aug 12, 2016 at 11:00
  • 3
    @EugeneBeresovsky To avoid NullReferenceException you can simply use the static method: String.Equals(string1, string2, StringComparison.Ordinal). Aug 12, 2016 at 11:01

9 Answers 9

344

InvariantCulture

Uses a "standard" set of character orderings (a,b,c, ... etc.). This is in contrast to some specific locales, which may sort characters in different orders ('a-with-acute' may be before or after 'a', depending on the locale, and so on).

Ordinal

On the other hand, looks purely at the values of the raw byte(s) that represent the character.


There's a great sample at http://msdn.microsoft.com/en-us/library/e6883c06.aspx that shows the results of the various StringComparison values. All the way at the end, it shows (excerpted):

StringComparison.InvariantCulture:
LATIN SMALL LETTER I (U+0069) is less than LATIN SMALL LETTER DOTLESS I (U+0131)
LATIN SMALL LETTER I (U+0069) is less than LATIN CAPITAL LETTER I (U+0049)
LATIN SMALL LETTER DOTLESS I (U+0131) is greater than LATIN CAPITAL LETTER I (U+0049)

StringComparison.Ordinal:
LATIN SMALL LETTER I (U+0069) is less than LATIN SMALL LETTER DOTLESS I (U+0131)
LATIN SMALL LETTER I (U+0069) is greater than LATIN CAPITAL LETTER I (U+0049)
LATIN SMALL LETTER DOTLESS I (U+0131) is greater than LATIN CAPITAL LETTER I (U+0049)

You can see that where InvariantCulture yields (U+0069, U+0049, U+00131), Ordinal yields (U+0049, U+0069, U+00131).

10
  • 32
    Ordinal comparison looks at the code points, not the bytes.
    – Joey
    Jan 23, 2012 at 10:16
  • 175
    I feel like is useful information, but does not actually answer the question. When determining Equality of two strings, is there any reason to use InvarintCulture instead of Ordinal? It seems that InvariantCulture would be used to Sort strings, and Ordinal should be used for Equality checking (we don't care that accented-a comes before or after a, it's simply different). Though, I myself am a little unsure of this point.
    – MPavlak
    Mar 21, 2012 at 16:32
  • 21
    See msdn.microsoft.com/en-us/library/ms230117%28v=vs.90%29.aspx and notice that string normalization and ordinal comparison is recommended.
    – MPavlak
    Mar 21, 2012 at 16:54
  • 27
    Ordinal is much quicker
    – Darren
    Feb 27, 2014 at 7:26
  • 10
    There is good performance test results published C# String Comparision Tests which tells the performance of each different string comparision methods and their time.
    – Kumar C
    Dec 13, 2014 at 22:44
329

It does matter, for example - there is a thing called character expansion

var s1 = "Strasse";
var s2 = "Straße";

s1.Equals(s2, StringComparison.Ordinal);           //false
s1.Equals(s2, StringComparison.InvariantCulture);  //true

With InvariantCulture the ß character gets expanded to ss.

9
  • 6
    For those that don't know ß it should be noted that ß at least in german equals to a double s, Source: en.wikipedia.org/wiki/%C3%9F
    – Peter
    Mar 2, 2016 at 7:46
  • 29
    That's not quite correct @Peter, you cannot use ß and ss interchangeably in German (I'm a native speaker). There are cases where both are legal (but often one is outdated / not recommended) and there are cases where only one form is allowed.
    – enzi
    Mar 22, 2016 at 17:22
  • 9
    This simple example clearly demonstrates the difference between the 2 comparisons. I think I'm getting this now.
    – BrianLegg
    Feb 20, 2017 at 16:51
  • 6
    Had to try it: ideone.com/j8DvDo so cool! A little lesson in German as well. Wondering what's the difference between ß and ss now...
    – Mzn
    May 10, 2018 at 0:58
  • 14
    Note that at least with .NET 5 both comparisons return false.
    – user764754
    Jan 21, 2021 at 12:49
141

Pointing to Best Practices for Using Strings in the .NET Framework:

  • Use StringComparison.Ordinal or StringComparison.OrdinalIgnoreCase for comparisons as your safe default for culture-agnostic string matching.
  • Use comparisons with StringComparison.Ordinal or StringComparison.OrdinalIgnoreCase for better performance.
  • Use the non-linguistic StringComparison.Ordinal or StringComparison.OrdinalIgnoreCase values instead of string operations based on CultureInfo.InvariantCulture when the comparison is linguistically irrelevant (symbolic, for example).

And finally:

  • Do not use string operations based on StringComparison.InvariantCulture in most cases. One of the few exceptions is when you are persisting linguistically meaningful but culturally agnostic data.
60

Another handy difference (in English where accents are uncommon) is that an InvariantCulture comparison compares the entire strings by case-insensitive first, and then if necessary (and requested) distinguishes by case after first comparing only on the distinct letters. (You can also do a case-insensitive comparison, of course, which won't distinguish by case.) Corrected: Accented letters are considered to be another flavor of the same letters and the string is compared first ignoring accents and then accounting for them if the general letters all match (much as with differing case except not ultimately ignored in a case-insensitive compare). This groups accented versions of the otherwise same word near each other instead of completely separate at the first accent difference. This is the sort order you would typically find in a dictionary, with capitalized words appearing right next to their lowercase equivalents, and accented letters being near the corresponding unaccented letter.

An ordinal comparison compares strictly on the numeric character values, stopping at the first difference. This sorts capitalized letters completely separate from the lowercase letters (and accented letters presumably separate from those), so capitalized words would sort nowhere near their lowercase equivalents.

InvariantCulture also considers capitals to be greater than lower case, whereas Ordinal considers capitals to be less than lowercase (a holdover of ASCII from the old days before computers had lowercase letters, the uppercase letters were allocated first and thus had lower values than the lowercase letters added later).

For example, by Ordinal: "0" < "9" < "A" < "Ab" < "Z" < "a" < "aB" < "ab" < "z" < "Á" < "Áb" < "á" < "áb"

And by InvariantCulture: "0" < "9" < "a" < "A" < "á" < "Á" < "ab" < "aB" < "Ab" < "áb" < "Áb" < "z" < "Z"

1
  • I took another look at this and noticed an inconsistency between the InvariantCulture example and my explanation on the handling of accented characters. The example appears to be correct, so I've corrected the explanation to be consistent. The InvariantCulture comparison does not stop at the first differing accent and appears to only consider an accent difference on the same letter if the rest of the strings match besides accents and case. An accent difference is then considered before an earlier case difference, so "Aaba" < "aába".
    – Rob Parker
    Jan 18, 2013 at 1:03
35

Although the question is about equality, for quick visual reference, here the order of some strings sorted using a couple of cultures illustrating some of the idiosyncrasies out there.

Ordinal          0 9 A Ab a aB aa ab ss Ä Äb ß ä äb ぁ あ ァ ア 亜 A
IgnoreCase       0 9 a A aa ab Ab aB ss ä Ä äb Äb ß ぁ あ ァ ア 亜 A
--------------------------------------------------------------------
InvariantCulture 0 9 a A A ä Ä aa ab aB Ab äb Äb ss ß ァ ぁ ア あ 亜
IgnoreCase       0 9 A a A Ä ä aa Ab aB ab Äb äb ß ss ァ ぁ ア あ 亜
--------------------------------------------------------------------
da-DK            0 9 a A A ab aB Ab ss ß ä Ä äb Äb aa ァ ぁ ア あ 亜
IgnoreCase       0 9 A a A Ab aB ab ß ss Ä ä Äb äb aa ァ ぁ ア あ 亜
--------------------------------------------------------------------
de-DE            0 9 a A A ä Ä aa ab aB Ab äb Äb ß ss ァ ぁ ア あ 亜
IgnoreCase       0 9 A a A Ä ä aa Ab aB ab Äb äb ss ß ァ ぁ ア あ 亜
--------------------------------------------------------------------
en-US            0 9 a A A ä Ä aa ab aB Ab äb Äb ß ss ァ ぁ ア あ 亜
IgnoreCase       0 9 A a A Ä ä aa Ab aB ab Äb äb ss ß ァ ぁ ア あ 亜
--------------------------------------------------------------------
ja-JP            0 9 a A A ä Ä aa ab aB Ab äb Äb ß ss ァ ぁ ア あ 亜
IgnoreCase       0 9 A a A Ä ä aa Ab aB ab Äb äb ss ß ァ ぁ ア あ 亜

Observations:

  • de-DE, ja-JP, and en-US sort the same way
  • Invariant only sorts ss and ß differently from the above three cultures
  • da-DK sorts quite differently
  • the IgnoreCase flag matters for all sampled cultures

The code used to generate above table:

var l = new List<string>
    { "0", "9", "A", "Ab", "a", "aB", "aa", "ab", "ss", "ß",
      "Ä", "Äb", "ä", "äb", "あ", "ぁ", "ア", "ァ", "A", "亜" };

foreach (var comparer in new[]
{
    StringComparer.Ordinal,
    StringComparer.OrdinalIgnoreCase,
    StringComparer.InvariantCulture,
    StringComparer.InvariantCultureIgnoreCase,
    StringComparer.Create(new CultureInfo("da-DK"), false),
    StringComparer.Create(new CultureInfo("da-DK"), true),
    StringComparer.Create(new CultureInfo("de-DE"), false),
    StringComparer.Create(new CultureInfo("de-DE"), true),
    StringComparer.Create(new CultureInfo("en-US"), false),
    StringComparer.Create(new CultureInfo("en-US"), true),
    StringComparer.Create(new CultureInfo("ja-JP"), false),
    StringComparer.Create(new CultureInfo("ja-JP"), true),
})
{
    l.Sort(comparer);
    Console.WriteLine(string.Join(" ", l));
}
4
  • 2
    Hmmm - OK, it's nice that you did this research, and posted your findings, although I'm not exactly sure what your point is. Anyway, Danish may not be one of the "most important cultures" (although 5 million Danes are actually rather fond of their culture), but if you throw "aa" in as an additional test string, and "da-DK" in as an additional test culture, you'll see some interesting results.
    – RenniePet
    Jun 11, 2014 at 0:09
  • 2
    @RenniePet Thanks for that. I added Danish, as it sorts quite differently than the 3 other cultures used. (As emoticons indicating irony don't seem to be as well-understood in the English language reading web as I would have assumed, I removed the "most important cultures" comment. After all, the BCL does not feature a CultureComparer which we could use to verify. For this table, the Danish culture(info) turned out to be very important.) Jun 11, 2014 at 0:39
  • 1
    Thanks. I did realize that your "most important cultures" comment was intended to be taken with a grain of salt - it's just that I've gotten too old to use emoticons. I figure that texting has become so common that using emoticons is sort of like explaining your jokes after you tell them, irrespective of whether or not anyone laughs. Incidentally, the other Scandinavian cultures (Finnish, Norwegian and Swedish) are the same as Danish, except for the very special handling of "aa" - which proves that Danish is the superior culture, of course.
    – RenniePet
    Jun 11, 2014 at 1:03
  • 1
    For what it's worth, Danish sorts ä and aa differently because of the location of the special letters æ (ae), ø (oe, ö), and å (aa, ä) at the end of the alphabet in the written order.
    – Alrekr
    Jun 4, 2018 at 8:34
28

Invariant is a linguistically appropriate type of comparison.
Ordinal is a binary type of comparison. (faster)
See http://www.siao2.com/2004/12/29/344136.aspx

7

Here is an example where string equality comparison using InvariantCultureIgnoreCase and OrdinalIgnoreCase will not give the same results:

string str = "\xC4"; //A with umlaut, Ä
string A = str.Normalize(NormalizationForm.FormC);
//Length is 1, this will contain the single A with umlaut character (Ä)
string B = str.Normalize(NormalizationForm.FormD);
//Length is 2, this will contain an uppercase A followed by an umlaut combining character
bool equals1 = A.Equals(B, StringComparison.OrdinalIgnoreCase);
bool equals2 = A.Equals(B, StringComparison.InvariantCultureIgnoreCase);

If you run this, equals1 will be false, and equals2 will be true.

1
  • Just to add another similar example but with string literals, if a="\x00e9" (e acute) and b="\x0065\x0301" (e combined with an acute accent), StringComparer.Ordinal.Equals(a, b) will return false while StringComparer.InvariantCulture.Equals(a, b) will return true. Jan 11, 2018 at 17:44
4

No need to use fancy unicode char exmaples to show the difference. Here's one simple example I found out today which is surprising, consisting of only ASCII characters.

According to the ASCII table, 0 (48, 0x30) is smaller than _ (95, 0x5F) when compared ordinally. InvariantCulture would say the opposite (PowerShell code below):

PS> [System.StringComparer]::Ordinal.Compare("_", "0")
47
PS> [System.StringComparer]::InvariantCulture.Compare("_", "0")
-1
1
-9

Always try to use InvariantCulture in those string methods that accept it as overload. By using InvariantCulture you are on a safe side. Many .NET programmers may not use this functionality but if your software will be used by different cultures, InvariantCulture is an extremely handy feature.

1
  • 6
    If your software will not be used by different cultures, it is much slower than Ordinal though.
    – Kyle
    Aug 7, 2012 at 23:51

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