If I've understood your question correctly, so your cost function is as Haile describes in his/her comment, there's an easy solution since you can reduce to a one-dimensional problem.
Note that in the Manhattan metric, the distance in columns that the cars must traverse is just summed with the distance in rows, so we can minimise them separately.
So we've reduced the problem to one dimension. To work out what was going on, I had to switch this to a continuous problem. So suppose that I have a density function, p(x), (let's say it's continuous with compact support, so that the maths works). Then the cost function is given by
Splitting this into two halves to get rid of the mod sign and differentiating (this is where you need to assume p(x) is well behaved), you get
Now, the optimal position for x0 is going to be the one that makes this derivative zero. But notice that this is the median of the distribution.
For the discrete setting, which was the original question, the same arguments work. Basically you can take a discrete derivative, which is E(k+1)-E(k). If you write a[n] for the number of cars at position n, then the cost function splits up as
Assuming I haven't made a stupid mistake, the discrete derivative comes out as
so the solution will be at the median again (rounded either way if you end up at a half-integer). To see why this is true, note that if k is a large negative number, this derivative is definitely negative (so increasing k by 1 will decrease the cost). Now, as k increases, the derivative slowly increases. At some point, it will become positive for the first time. This happens as soon as k+1 is larger than the median. After that, it will stay positive, so the correct k to choose is the largest k less than or equal to the median.
The original question was in two dimensions, so you need to run this twice, once for each axis.