Imagine you have a dancing robot in `n`

-dimensional euclidean space starting at origin `P_0`

= `(0,0,...,0)`

.

The robot can make `m`

types of dance moves `D_1, D_2, ..., D_m`

`D_i`

is an `n`

-vector of integers `(D_i_1, D_i_2, ..., D_i_n)`

If the robot makes dance move `i`

than its position changes by `D_i`

:

`P_{t+1} = P_t + D_i`

The robot can make any of the dance moves as many times as he wants and in any order.

Let a *k-dance* be defined as a sequence of k dance moves.

Clearly there are `m^k`

possible k-dances.

*We are interested to know the set of possible end positions of a k-dance, and for each end position, how many k-dances end at that location.*

One way to do this is as follows:

```
P0 = (0, 0, ..., 0);
S[0][P0] = 1
for I in 1 to k
for J in 1 to m
for P in S[I-1]
S[I][P + D_J] += S[I][P]
```

Now `S[k][Q]`

will tell you how many k-dances end at position Q

Assume that `n`

, `m`

, `|D_i|`

are small (less than 5) and `k`

is less than 40.

Is there a faster way? Can we calculate `S[k][Q]`

"directly" somehow with some sort of linear algebra related trick? or some other approach?