I have two sets A and B. Set A contains unique elements. Set B contains all elements. Each element in the B is a 10 by 10 matrix where all entries are either 1 or 0. I need to scan through set B and everytime i encounter a new matrix i will add it to set A. Therefore set A is a subset of B containing only unique matrices.

Here is some code, maybe not very efficient :
You can use EDIT : I inverted A and B in my first post. It's correct now. Sorry for the inconvenience. I also corrected the comparison functor. 


It seems like you might really be looking for a way to manage a large, sparse array. Trivially, you could use a hash map with your giant index as your key, and your data as the value. If you talk more about your problem, we might be able to find a more appropriate data structure for your problem. Update: If set B is just some set of matrices and not the set of all possible 10x10 binary matrices, then you just want a sparse array. Every time you find a new matrix, you compute its key (which could simply be the matrix converted into a 100 digit binary value, or even a 100 character string!), look up that index. If no such key exists, insert the value 1 for that key. If the key does exist, increment and restore the new value for that key. 


Good, that means it can be represented by a 100bit number. Let's round that up to 128 bits (sixteen bytes). One approach is to use linked lists  create a structure like (in C):
and maintain the entire list The performance will be somewhat less ^{(a)} than using the 100bit number as an array index into a truly immense (to the point of impossible given the size of the known universe) array. When it comes time to insert a new item into ^{(a)} Though probably not unmanageably so  there are options you can take to improve the speed. One possibility is to use skip lists, for faster traversal during searches. These are another pointer that references not the next element but one 10 (or 100 or 1000) elements along. That way you can get close to the desired element reasonably quickly and just do the onestep search after that point. Alternatively, since you're talking about bits, you can divide You could also use a hash on the 100bit value to generate a smaller key which you can use as an index into an array/list, but I don't think that will give you any real advantage over the method in the previous paragraph. 


Convert each matrix into a string of 100 binary digits. Now run it through the Linux utilities:
If you really need to do this in C++, it is possible to implement your own merge sort, then the 


You don't need N buckets where N is the number of all possible inputs. A binary tree will just do fine. This is implemented with


