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`

. )