This is basically a dynamic programming problem. You don't really have to consider all the possible paths at each step since the details of the paths don't affect future decisions. For each cell, you need to know the maximum amount that can be collected if you go a particular direction and taking a particular number of moves. Nothing else affects your decisions.

```
def bestAmount(x,y,direction,n_moves):
# If this position is off the grid, then this isn't a valid state
if x<0 or x>=width or y>=height:
return None
if n_moves==0:
# We came to the last move.
if y!=height-1:
# If we're not at the bottom row then this isn't a valid path.
return None
# Otherwise, the final cell value is part of our total.
return cellValue(x,y)
if direction=='down':
# If we came down to get to this position, then the next move
# can be either left, right, or down
left = bestAmount(x-1,y,'left',n_moves-1)
right = bestAmount(x+1,y,'right',n_moves-1)
down = bestAmount(x,y+1,'down',n_moves-1)
return max(left,right,down)+cellValue(x,y)
if direction=='left':
# If we moved left to get to this position, then
# we can't go right, since we would be visiting the same position again.
left = bestAmount(x-1,y,'left',n_moves-1)
down = bestAmount(x,y+1,'down',n_moves-1)
return max(left,down)+cellValue(x,y)
if direction=='right':
# same logic as for left, but opposite.
right = bestAmount(x+1,y,'right',n_moves-1)
down = bestAmount(x,y+1,'down',n_moves-1)
return max(right,down)+cellValue(x,y)
def solve(n_moves):
# Start by pretending we entered the starting cell by going down
return bestAmount(0,0,'down',n_moves)
```

If bestAmount is memoized, then you get a fairly efficient solution since the number of possibilities is relatively limited.

Treating it as a dynamic programming problem will get you an even more efficient solution though.