I believe you can still use the basic idea of XOR to solve this problem in a clever fashion.

First, let's change the problem so that one number appears once and all other numbers appear three times.

**Algorithm:**

Here `A`

is the array of length `n`

:

```
int ones = 0;
int twos = 0;
int not_threes, x;
for (int i=0; i<n; ++i) {
x = A[i];
twos |= ones & x;
ones ^= x;
not_threes = ~(ones & twos);
ones &= not_threes;
twos &= not_threes;
}
```

And the element that occurs precisely once is stored in `ones`

. This uses `O(n)`

time and `O(1)`

space.

I believe I can extend this idea to the general case of the problem, but possibly one of you can do it faster, so I'll leave this for now and edit it when and if I can generalize the solution.

**Explanation:**

If the problem were this: "one element appears once, all others an even number of times", then the solution would be to XOR the elements. The reason is that `x^x = 0`

, so all the paired elements would vanish leaving only the lonely element. If we tried the same tactic here, we would be left with the XOR of distinct elements, which is not what we want.

Instead, the algorithm above does the following:

`ones`

is the XOR of all elements that have appeared exactly once so far
`twos`

is the XOR of all elements that have appeared exactly twice so far

Each time we take `x`

to be the next element in the array, there are three cases:

- if this is the first time
`x`

has appeared, it is XORed into `ones`

- if this is the second time
`x`

has appeared, it is taken out of `ones`

(by XORing it again) and XORed into `twos`

- if this is the third time
`x`

has appeared, it is taken out of `ones`

and `twos`

.

Therefore, in the end, `ones`

will be the XOR of just one element, the lonely element that is not repeated. There are 5 lines of code that we need to look at to see why this works: the five after `x = A[i]`

.

If this is the first time `x`

has appeared, then `ones&x=ones`

so `twos`

remains unchanged. The line `ones ^= x;`

XORs `x`

with `ones`

as claimed. Therefore `x`

is in exactly one of `ones`

and `twos`

, so nothing happens in the last three lines to either `ones`

or `twos`

.

If this is the second time `x`

has appeared, then `ones`

already has `x`

(by the explanation above), so now `twos`

gets it with the line `twos |= ones & x;`

. Also, since `ones`

has `x`

, the line `ones ^= x;`

removes `x`

from `ones`

(because `x^x=0`

). Once again, the last three lines do nothing since exactly one of `ones`

and `twos`

now has `x`

.

If this is the third time `x`

has appeared, then `ones`

does not have `x`

but `twos`

does. So the first line let's `twos`

keep `x`

and the second adds `x`

to `ones`

. Now, since both `ones`

and `twos`

have `x`

, the last three lines remove `x`

from both.

**Generalization:**

If some numbers appear 5 times, then this algorithm still works. This is because the 4th time `x`

appears, it is in neither `ones`

nor `twos`

. The first two lines then add `x`

to `ones`

and not `twos`

and the last three lines do nothing. The 5th time `x`

appears, it is in `ones`

but not `twos`

. The first line adds it to `twos`

, the second removed it from `ones`

, and the last three lines do nothing.

The problem is that the 6th time `x`

appears, it is taken from `ones`

and `twos`

, so it gets added back to `ones`

on the 7th pass. I'm trying to think of a clever way to prevent this, but so far I'm coming up empty.