I'd like to elaborate on @supercat's correct and fast solution and describe an algorithm that computes a minimal length sum in addition to computing the length of such a sum.

## Algorithm

Find the least integer k such that t_k := 1 + 2 + 3 + ... + k >= |n| and t_k has the same parity as |n|.
Then flip the signs of the summands of t_k in a systematic way to total n.

Here are the details.
Notice that t_k = k(k + 1)/2, a triangular number.
Setting t_k = |n| and solving for k gives the ceiling of (-1 + sqrt(1 + 8|n|))/2.
So k equals the ceiling or 1 or 2 plus it, whichever of those three numbers has the same parity as n and is least.
Here we're using the fact that the set {t, t + s, t + s + (s + 1)} of three consecutive triangular numbers contains both even and odd numbers for any positive integers t, s.
(Simply check all four parity possibilities for t and s.)

To find a minimal length sum for n, first compute d := (t_k - n)/2.
Because t_k >= |n| and t_k and n have the same parity, d lies in the set {0, 1, 2, ..., t_k}.
Now repeatedly subtract: d = a_k (k) + r_k, r_k = a_{k-1} (k-1) + r_{k-1}, ..., r_2 = a_1 (1) + r_1, choosing each a_i maximally in {0, 1}.
By the lemma below, r_1 = 0.
So d = sum_{i=1}^k a_i i.
Thus n = t_k - 2d = sum_{i=1}^k i - sum_{i=1}^k 2a_i i = sum_{i=1}^k (1 - 2a_i) i and 1 - 2a_i lies in {-1, 1}.
So the sequence b_i := 1 - 2a_i is a path, and by the minimality of k, b_i is a minimal path.

## Algorithm example

Consider the target number n=12. According to Algorithm 3, the possibilities for k are 5, 6, or 7. The corresponding values of t_k are 15, 21, and 28. Since 28 is the least of these with the same parity as n, we see that k=7. So d = (t_k - n)/2 = 8, which we write as 1 + 7 according to the algorithm. Thus a shortest path to 12 is -1 + 2 + 3 + 4 + 5 + 6 - 7.

I say *a* shortest path, because shortest paths aren't unique in general.
For example, 1 + 2 -3 + 4 - 5 + 6 + 7 also works.

## Algorithm correctness

Lemma: Let A_k = {0, 1, 2, ..., t_k}.
Then a number lies in A_k if and only if it can be expressed as a sum sum_{i=1}^k a_i i for some sequence a_i in {0, 1}.

Proof: By induction on k.
First, 0 = sum_{i=1}^0 1, the empty sum.
Now suppose the result holds for all k - 1 >= 0 and suppose a number d lies in A_k.
Repeatedly subtract: d = a_k (k) + r_k, r_k = a_{k-1} (k-1) + r_{k-1}, ..., choosing each a_i = 0 or 1 maximally in {0, 1} and stopping when the first r_j lies in A_j for some j < k.
Then by the induction hypothesis, r_j = sum_{i=0}^j b_i i for some b_i in {0, 1}.
Then d = r_j + sum_{i=j+1}^k a_k i, as desired.
Conversely, a sum s := sum_{i=1}^k a_i i for a_i in {0,1} satisfies 0 <= s <= sum_{i}^k i = t_k, and so s lies in A_k.

## Algorithm time complexity

Assuming that arithmetic operations are constant time, it takes O(1) time to compute k from n, and hence the length of a minimal path to n.
Then it takes O(k) time to find a minimal length sum for d, then O(k) time to use that sum to produce a minimal length sum for n.
So O(k) = O(sqrt(n)) time all up.

2, is getting to3OK? – angelatlarge Mar 14 '13 at 16:55