This algorithm is O(1) space (with some cheating), O(n) time (average), needs the source array to be non-const and destroys it at the end. Also it limits possible values in the array (three bits of each value should be reserved for the algorithm).
Half of the answer is already in the question. Use hashmap. If a number is hit twice, use index difference, update the best so far result and remove this number from the hashmap to free space . To make it O(1) space, just reuse the source array. Convert the array to hashmap in-place.
Before turning an array element to the hashmap cell, remember its value and position. After this it may be safely overwritten. Then use this value to calculate a new position in the hashmap and overwrite it. Elements are shuffled this way until an empty cell is found. To continue, select any element, that is not already reordered. When everything is reordered, every int pair is definitely hit twice, here we have an empty hashmap and an updated best result value.
One reserved bit is used while converting array elements to the hashmap cells. At the beginning it is cleared. When a value is reordered to the hashmap cell, this bit is set. If this bit is not set for overwritten element, this element is just taken to be processed next. If this bit is set for element to be overwritten, there is a conflict here, pick first unused element (with this bit not set) and overwrite it instead.
2 more reserved bits are used to chain conflicting values. They encode positions where the chain is started/ended/continued. (It may be possible to optimize this algorithm so that only 2 reserved bits are needed...)
A hashmap cell should contain these 3 reserved bits, original value index, and some information to uniquely identify this element. To make this possible, a hash function should be reversible so that part of the value may be restored given its position in the table. In simplest case, hash function is just
ceil(log(n)) least significant bits. Value in the table consists of 3 fields:
3 reserved bits
32 - 3 - (ceil(log(n))) high-order bits from the original value
ceil(log(n)) bits for element's position in the original array
Time complexity is O(n) only on average; worst case complexity is O(n^2).
Other variant of this algorithm is to transform the array to hashmap sequentially: on each step
2^m first elements of the array converted to hashmap. Some constant-sized array may be interleaved with the hashmap to improve performance when
m is low. When
m is high, there should be enough int pairs, which are already processed, and do not need space anymore.