Let `B`

be the list of pairwise sums, with `B[0] <= B[1] <= ... <= B[m-1]`

and let `A`

be the original list of numbers that we're trying to find, with `A[0] < A[1] < ... < A[n-1]`

, where `m = n(n-1)/2`

.

**Given **`A[0]`

, compute `A`

in polynomial time

Build `A`

up from smallest element to largest. Suppose that we already know `A[0]`

. Then, since `B[0]`

is the smallest element in `B`

, it can only arise as `A[0] + A[1]`

. Similarly, `B[1]`

must equal `A[0] + A[2]`

. Therefore, if we know `A[0]`

, we can compute `A[1]`

and `A[2]`

.

After that, however, this pattern breaks down. `B[2]`

could either be `A[0] + A[3]`

or `A[1] + A[2]`

and without prior knowledge, we cannot know which one it is. However, if we know `A[0]`

, we can compute `A[1]`

and `A[2]`

as described above, and then remove `A[1] + A[2]`

from `B`

. The next smallest element is then guaranteed to be `A[0] + A[3]`

, which allows us to find `A[3]`

. Continuing like this, we can find all of `A`

without ever backtracking. The algorithm looks something like this:

```
for i from 1 to n-1 {
// REMOVE SEEN SUMS FROM B
for j from 0 to i-2 {
remove A[j]+A[i-1] from B
}
// SOLVE FOR NEXT TERM
A[i] = B[0] - A[0]
}
return A
```

Here's how this works from your example where `B = [4,5,7,10,12,13]`

if we know `A[0]=1`

:

```
start
B = [4,5,7,10,12,13]
A[0] = 1
i=1:
B = [4,5,7,10,12,13]
A[1] = 4-1 = 3
i=2:
Remove 1+3 from B
B = [5,7,10,12,13]
A[2] = 5-1 = 4
i=3:
Remove 1+4 and 3+4 from B
B = [10,12,13]
A[3] = 10-1 = 9
end
Remove 1+9 and 3+9 and 4+9 from B
B = []
A = [1,3,4,9]
```

So it all comes down to knowing `A[0]`

, from which we can compute the rest of `A`

.

**Compute **`A[0]`

in polynomial time

We can now simply try every possibility for `A[0]`

. Since we know `B[0] = A[0] + A[1]`

, we know `A[0]`

must be an integer between `0`

and `B[0]/2 - 1`

. We also know that

```
B[0] = A[0] + A[1]
B[1] = A[0] + A[2]
```

Moreover, there is some index `i`

with `2 <= i <= n-1`

such that

```
B[i] = A[1] + A[2]
```

Why? Because the only entries potentially smaller than `A[1]+A[2]`

are of the form `A[0] + A[j]`

, and there are at most `n-1`

such expressions. Therefore we also know that

```
A[0] = (B[0]+B[1] - B[i])/2
```

for some `2 <= i <= n-1`

. This, together with the fact that `A[0]`

lies between `0`

and `B[0]/2-1`

gives only a few possibilities for `A[0]`

to test.

For the example, there are two possibilities for `A[0]`

: `0`

or `1`

. If we try the algorithm with `A[0]=0`

, here's what happens:

```
start
B = [4,5,7,10,12,13]
A[0] = 0
i=1:
B = [4,5,7,10,12,13]
A[1] = 4-0 = 4
i=2:
Remove 0+4 from B
B = [5,7,10,12,13]
A[2] = 5-0 = 5
i=3:
Remove 0+5 and 4+5 from B
B = !!! PROBLEM, THERE IS NO 9 IN B!
end
```