I have solved the following algorithm shown below.

```
public static long park(int n)
{
// precondition: n >= 1
// postcondition: Return the number of ways to park 3 vehicles,
// designated 1, 2 and 3 in n parking spaces, without leaving
// any spaces empty. 1 takes one parking space, 2 takes two spaces,
// 3 takes three spaces. Each vehicle type cannot be distinguished
// from others of the same type, ie for n=2, 11 counts only once.
// Arrangements are different if their sequences of vehicle types,
// listed left to right, are different.
// For n=1: 1 is the only valid arrangement, and returns 1
// For n=2: 11, 2 are arrangements and returns 2
// For n=3: 111, 12, 21, 3 are arrangements and returns 4
// For n=4: 1111,112,121,211,22,13,31 are arrangements and returns 7
if(n==1)
{ return 1; }
else if(n==2)
{ return 2; }
else if(n==3)
{ return 4; }
else
{
return (park(n-1) + park(n-2) + park(n-3));
}
}
```

What I need help on is figuring out a followup problem which is to include empty parking spaces in the permutation. This should be solved recursively.

```
Let's designate a single empty space as E.
For n=1: 1,E and returns 2
For n=2: 11,2,EE,1E,E1 and returns 5
For n=3: 111,12,21,3,EEE,EE1,E1E,1EE,11E,1E1,E11,2E,E2 and returns 13
For n=4: there are 7 arrangements with no E, and 26 with an E, returns 33
```

I've spent many hours on this. I know how many arrangements there are without an empty space from the above algorithm. So I've been trying to figure out how many arrangements there are with 1 or more empty spaces. The union of these two sets should give me the answer. For n, the number of single space permutations with one or more empty spaces is 2^n-1. But I don't think this will help me in a recursive solution.

Any guidance would be appreciated.

muchfaster DP solution. – quasiverse Sep 16 '11 at 4:49