Can anybody please tell me why the string comparisons below deliver these results?

>> "1040"<="10000"  

I've tried the string comparison in both C and Python, the result is obviously correct, I just can't figure out how the result is calculated...

P.S.: I know that comparing strings of different length is something you shouldn't do, but I'm still wondering about the logic behind the above lines ;-)

11 Answers 11


"1" is equal to "1".

"0" comes before "2" (so "1040" < "12000").

"4" comes after "0" (so "1040" > "10000").


The fancy word here describing this ordering is "lexicographical order" (and sometimes "dictionary order"). In everyday language we just refer to it as "alphabetical order". What this means is that we place first an ordering on our alphabet (A, B, ... Z, etc.) and then to compare two words over this alphabet we compare one character at a time until we find two non-equal characters in the same position and return the comparison between these two characters.

Example: The "natural" ordering on the alphabet { A, B, C, ..., Z } is that A < B < C < ... < Z. Given two words s = s_1s_2...s_m and t = t_1t_2...t_n we compare s_1 to t_1. If s_1 < t_1 we say that s < t. If s_1 > t_1 we say that s > t. If s_1 = t_1 we recurse on the words s_2...s_m and t_2...t_n. For this to work we say that the empty string is less than all non-empty strings.

In the old days, before Unicode and the like, the ordering on our symbols was just the ordering for the ASCII character codes. So then we have 0 < 1 < 2 < ... < 9 < ... < A < B < C < ... Z < ... < a < b < c < ... < z. It's more complicated in the days of Unicode, but the same principle applies.

Now, what all this means is that if we want to compare 1040 and 12000 we would use the following:

1040 compare to 12000 is equal to 040 compare to 2000 which gives 040 < 2000 because 0 < 2 so that, finally, 1040 < 12000.

1040 compare to 10000 is equal to 040 compare to 0000 is equal to 40 compare to 000 which gives 40 > 000 because 4 > 0 so that, finally, 1040 > 10000.

The key here is that these are strings and do not have a numerical meaning; they are merely symbols and we have a certain ordering on our symbols. That is, we could achieve exactly the same answer if we replaced 0 by A, 1 by B, ..., and 9 by J and said that A < B < C < ... < J. (In this case we would be comparing BAEA to BAAAA and BAEA to BCAAA. )

  • And, as a consequence of your empty string rule, a shorter string is "less" than a longer string.
    – seh
    Dec 7, 2009 at 21:51
  • @seh: No B is greater than AB even though B is shorter than AB. However, your statement is correct if you say that a prefix is always less than any nontrivial extension of the prefix.
    – jason
    Dec 7, 2009 at 22:01

Think alphabetized.

  • To be specific, think "ABCB" <= "ABBBB". Dec 7, 2009 at 21:32
  • 1
    @Pavel Minaev: are you sure?
    – Javier
    Dec 7, 2009 at 22:05
  • I meant "think about what it evaluates to, and why". Dec 7, 2009 at 23:12

The strings are compared, one character at a time, from left to right:


There's nothing wrong with comparing strings of different lengths.


You're experiencing lexicographical ordering.

There are some generalized algorithms for this ordering in the book Elements of Programming. Search for the word lexicographical.


It compares the "numbers" on a character by character basis. In the first case, "1" == "1", but then "0" < "2" in ASCII (and as an integer) so it returns true.

In the second case, 1==1, 0==0, but 4 > 0, so it returns false.

And there's nothing wrong with comparing strings of a different length... but you should use the appropriate string comparison method.


In C, string comparisons are done character by character. In the first case, the first characters of the stings are equal, so it comes down to the second character: '0' is < '2', so "1040" < "12000". In the second case, the first two characters of the strings are equal, so the third character is the basis -- '4' > '0', so "1040" > "10000".

If you want them compared as numbers, you'll need to convert them to numbers first, then do the comparison.


To expand on the John P's answer, think of the strings as words, and read them left-to-right.

To look at it another way,

BAEA would come before BCAAA but after BAAAA


It compares each character since you are comparing strings. If you wish to compare the numbers, then make them a numerical type.


"10000" <= "1040" <= "12000" in the same way that "fabricate" <= "fact" <= "foolish".


how about making them the same length?

That would unify numbers and alphas

1040 becomes 01040

01040 < 12000 now it makes sense

maybe that is why he felt it was wrong to compare strings of different length when the strings are numbers they should be the same length

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