Disproof of algorithm in OP for k >= 7
This algorithm uses the possibility to recursively split a set of k unique values into two groups using value of a single bit when at least one of these groups is XORed to a nonzero value. For example, the following numbers
may be split into
using the value of the least significant bit.
If properly implemented, this works for k <= 6. But this approach fails for k = 8 and k = 7. Let's assume m = 4 and use 8 even numbers from 0 to 14:
Each bit, except the least significant one, has exactly 4 nonzero values. If we try to partition this set, because of this symmetry, we'll always get a subset with 2 or 4 or 0 nonzero values. XOR of these subsets is always 0. Which does not allow algorithm to make any split, so
else part just prints the XOR of all these unique values (a single zero).
3x + 1 trick does not help: it only shuffles these 8 values and toggles the least significant bit.
Exactly the same arguments are applicable for k = 7 if we remove the first (all-zero) value from the above subset.
Since any group of unique values may be split into a group of 7 or 8 values and some other group, this algorithm also fails for k > 8.
It is possible not to invent a completely new algorithm, but instead modify the algorithm in OP, making it work for any input values.
Each time the algorithm accesses an element of the input array, it should apply some transformation function to this element:
y=transform(x). This transformed value
y may be used exactly as
x was used in the original algorithm - for partitioning the sets and XORing the values.
transform(x)=x (unmodified original algorithm). If after this step we have less than k results (some of the results are several unique values XORed), we change
transform to some hash function and repeat computations. This should be repeated (each time with different hash function) until we get exactly k values.
If these k values are obtained on the first step of the algorithm (without hashing), these values are our result. Otherwise we should scan the array once more, computing hash of each value and reporting those values, that match one of k hashes.
Each subsequent step of computations with different hash function may be performed either on the original set of k values or (better) separately on each of the subsets, found on previous step.
To obtain different hash function for each step of the algorithm, you can use Universal hashing. One necessary property for the hash function is reversibility - original value should be (in theory) reconstructible from the hash value. This is needed to avoid hashing of several "unique" values to the same hash value. Since using any reversible m-bit hash function has not much chances to solve the problem of "counterexample", hash values should be longer than m bits. One simple example of such hash function is concatenation of the original value and some one-way hash function of this value.
If k is not very large, it is not likely that we get a set of data similar to that counter-example. (I have no proof that there are no other "bad" data patterns, with different structure, but let's hope they are also not very probable). In this case average time complexity is not much larger than O(k * m2 * n).
Other improvements for the original algorithm
- While computing the XOR of all the (yet unpartitioned) values it is reasonable to check for a unique zero value in the array. If there is one, just decrement k.
- On each recursion step we cannot always know the exact size of each partition. But we know if it is odd or even: each split on a non-zero bit gives odd-sized subset, the other subset's parity is "toggled" parity of the original subset.
- On the latest recursion steps, when the only non-split subset is of size 1, we may skip the search for splitting bit and report the result immediately (this is an optimization for very small k).
- If we get an odd-sized subset after some split (and if we don't know for sure its size is 1), scan the array and try to find a unique value, equal to XOR of this subset.
- There is no need to iterate through every bit to split even-sized set. Just use any non-zero bit of its XORed values. XORing one of the resulting subsets may produce zero, but this split is still valid because we have odd number of "ones" for this splitting bit but even set size. This also means that any split, that produces even-sized subset which is non-zero when XORed, is a valid split, even if the remaining subset XORs to zero.
- You shouldn't continue splitting bit search on each recursion (like
solve(ary, h + 1...). Instead you should restart search from the beginning. It is possible to split the set on bit 31, and have the only splitting possibility for one of the resulting subsets on bit 0.
- You shouldn't scan the whole array twice (so second
y = compute_xors(ary, m, bits) is not needed). You already have XOR of the whole set and XOR of a subset where the splitting bit is non-zero. Which means you can compute
y = x ^ old_xor.
Proof of algorithm in OP for k = 3
This is a proof not for the actual program in OP, but for its idea. The actual program currently rejects any split when one of the resulting subsets is zero. See suggested improvements for the cases when we may accept some of such splits. So the following proof may be applied to that program only after
if x is None or y is None is changed to some condition that takes into account parity of the subset sizes or after a preprocessing step is added to exclude unique zero element from the array.
We have 3 different numbers. They should be different in at least 2 bit positions (if they are different in only one bit, the third number must be equal to one of the others). Loop in the
solve function finds leftmost of these bit positions and partitions these 3 numbers into two subsets (of a single number and of 2 distinct numbers). The 2-number subset has equal bits in this bit position, but the numbers still should be different, so there should be one more splitting bit position (obviously, to the right of the first one). Second recursion step easily splits this 2-number subset into two single numbers. Trick with
i * 3 + 1 is redundant here: it only doubles complexity of the algorithm.
Here is an illustration for the first split in a set of 3 numbers:
We have a loop that iterates through every bit position and computes XOR of the whole words, but separately, one XOR value (A) for true bits in given position, other XOR value (B) for false bit.
If number A has zero bit in this position, A contains XOR of some even-sized subset of values, if non-zero - odd-sized subset. The same is true for B. We are interested only in the even-sized subset.
It may contain either 0 or 2 values.
While there is no difference in the bit values (bits z, v, w), we have A=B=0, which means we cannot split our numbers on these bits.
But we have 3 non-equal numbers, which means at some position (1) we should have different bits (x and y). One of them (x) can be found in two of our numbers (even-sized subset!), other (y) - in one number.
Let's look at the XOR of values in this even-sized subset. From A and B select value (C), containing bit 0 at position 1. But C is just a XOR of two non-equal values.
They are equal at bit position 1, so they must differ in at least one more bit position (position 2, bits a and b). So C != 0 and it corresponds to the even-sized subset.
This split is valid because we can split this even-sized subset further either by very simple algorithm or by next recursion of this algorithm.
If there are no unique zero elements in the array, this proof may be simplified. We always split unique numbers into 2 subsets - one with 2 elements (and it cannot XOR to zero because elements are different), other with one element (non-zero by definition). So the original program with little pre-processing should work properly.
Complexity is O(m2 * n). If you apply the improvements I suggested earlier, the expected number of times this algorithm scans the array is m / 3 + 2. Because the first splitting bit position is expected to be m / 3, a single scan is needed to deal with 2-element subset, every 1-element subset does not need any array scans, and one more scan is needed initially (outside of
Proof of algorithm in OP for k = 4 .. 6
Here we assume that all the suggested improvements to the original algorithm are applied.
k=4 and k=5: Since there is at least one position with different bits, this set of numbers can be split in such a way that one of the subsets has size 1 or 2. If subset's size is 1, it is non-zero (we have no zero unique values). If subset's size is 2, we have XOR of two different numbers, which is non-zero. So in both cases the split is valid.
k=6: If XOR of the whole set is non-zero, we can split this set by any position where this XOR has non-zero bit. Otherwise we have even number of non-zero bit in each position. Since there is at least one position with different bits, this position splits the set into subsets of sizes 2 and 4. Subset of size 2 has always non-zero XOR because it contains 2 different numbers. Again, in both cases we have the valid split.
Disproof for k >= 7 shows the pattern where original algorithm does not work: we have a subset of size greater than 2 and at each bit position we have even number of non-zero bits. But we can always find a pair of positions where non-zero bits overlap in single number. In other words, it is always possible to find a pair of positions in the subset of size 3 or 4 with non-zero XOR of all bits in the subset in both positions. This suggest us to use an additional split-position: iterate through bit positions with two separate pointers, group all numbers in the array into two subsets where one subset has both non-zero bits in these positions, and other - all the remaining numbers. This increases the worst case complexity my m, but allows more values for k. Once there is no more possible to obtain a subset of size less than 5, add the third "splitting pointer", and so on. Each time k doubles, we may need an additional "splitting pointer", which increases the worst case complexity my m once more.
This might be considered as a sketch of a proof for the following algorithm:
- Use original (improved) algorithm to find zero or more unique values and zero or more non-splittable subsets. Stop when there are no more non-splittable subsets.
- For any of these non-splittable subsets, try to split it while increasing the number of "splitting pointers". When split is found, continue with step 1.
Worst case complexity is O(k * m2 * n * mmax(0, floor(log(floor(k/4))))), which may be approximated by O(k * n * mlog(k)) = O(k * n * klog(m)).
Expected run time of this algorithm for small k is a little bit worse than for probabilistic algorithm, but still not much larger than O(k * m2 * n).