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I would like to have a user-defined key in a C++ std::map. The key is a binary representation of an integer set with maximum value 2^V so I can't represent all 2^V possible values. I do so by means of an efficient binary set representation, i.e., an array of uint64_t.

Now the problem is that to put this user-defined bitset as key in a std::map, I need to define a valid comparison between bitset values but if I have a maximum size of, say, V=1000, then I cannot get a number I can compare, let alone aggregating them all i.e., 2^1000 is not representable.

Therefore my question is, suppose I have two different sets (by setting the right bits in my bitset representation) and I cannot represent the final number because it will overflow:

id_1 = 2^0 + 2^1 + ... + 2^V

id_2 = 2^0 + 2^1 + ... + 2^V

Is there a suitable transformation that would lead to a value I can compare? I need to be able to say id_1 < id_2 so I would like to transform a sum of exponentials to a value that is representable BUT maintaining the invariant of the "less than". I was thinking along the lines of e.g. applying a log transformation in a clever way to preserve "less than".

Here is an example:

set_1 = {2,3,4}; set_2 = {8}

id(set_1) = 2^2 + 2^3 + 2^4 = 28; id(set_2) = 2^8 = 256

id(set_1) < id(set_2)

Perfect! How about a general set that can have {1,...,V}, and thus 2^V possible subsets?

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Why don't you compare the values themselves? You will always suffer from the mapping of your ids to the limited integers being not bijective. – Nobody Oct 4 '12 at 10:14
Exactly. Whenever you try to convert from one set to a smaller one, you run into the chance of conflicts and incorrect comparison. A bit by bit comparison seems like the way to go here. – Sabre Runner Oct 4 '12 at 10:17
bit by bit comparison doesn't solve the problem. Suppose you have an array of int64_t and the further you go the exponent gets e.g. 2^5000 how can you compare without aggregating? I simply don't see how. – Giovanni Azua Oct 4 '12 at 10:21
"how can you compare without aggregating" - lexicographically? – ltjax Oct 4 '12 at 10:32
Don't use uint64_t unless your application absolutely requires exactly 64 bits. In general, use uint_least64_t, since uint64_t is not required to exist. – Pete Becker Oct 4 '12 at 11:11

1 Answer 1

up vote 4 down vote accepted

I do so by means of an efficient binary set representation, i.e., an array of uint64_t.

Supposing that this array is accessed via a data member ra of the key type Key, and both arrays are of length N, then you want a comparator something like this:

bool operator<(const Key &lhs, const Key &rhs) {
    return std::lexicographical_compare(lhs.ra, &lhs.ra[N], rhs.ra, &rhs.ra[N]);

This implicitly considers the array to be big-endian, i.e. the first uint64_t is the most significant. If you don't like that, that's fair enough, since you might already have in mind some relative significance for whatever order you've stored your V bits into your array. There's no great mystery to lexicographical_compare, so just look at an example implementation and modify as required.

This is called "lexicographical order". Other than the facts that I've used uint64_t instead of char and both arrays are the same length, it is how strings are compared[*] -- in fact the use of uint64_t isn't important, you could just use std::memcmp in your comparator instead of comparing 64-bit chunks. operator< for strings doesn't work by converting the whole string to an integer, and neither should your comparator.

[*] until you bring locale-specific collation rules into play.

share|improve this answer
You can also use std::lexicographical_compare, which does exactly this. – interjay Oct 4 '12 at 10:35
@interjay: well I never, that's been there all along. OK. – Steve Jessop Oct 4 '12 at 10:37
Thank you! I actually thought of lexicographical ordering but using a string, then I figured it would be a waste to have such possibly very long strings ... I didnt know I could do lexicographical ordering on the uint64_t arrays directly. Thanks! – Giovanni Azua Oct 4 '12 at 12:00
@Giovanni: yep, lexicographical order applies in principle to any sequences (not necessarily the same length) of values taken from any type that itself is ordered. lexicographical_compare implements that in C++. – Steve Jessop Oct 5 '12 at 9:01

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