I have a linear recurrence problem where the next element relies on more than just the prior value, e.g. the Fibonacci sequence. One method calculating the n^{th} element is to define it via a function call, e.g.

```
Fibonacci[0] = 0; Fibonacci[1] = 1;
Fibonacci[n_Integer?Positive] := Fibonacci[n] + Fibonacci[n - 1]
```

and for the sequence I'm working with, that is exactly what I do. (The definition is inside of a `Module`

so I don't pollute `Global``

.) However, I am going to be using this with 2^{10} - 2^{13} points, so I'm concerned about the extra overhead when I just need the last term and none of the prior elements. I'd like to use `Fold`

to do this, but `Fold`

only passes the immediately prior result which means it is not directly useful for a general linear recurrence problem.

I'd like a pair of functions to replace `Fold`

and `FoldList`

that pass a specified number of prior sequence elements to the function, i.e.

```
In[1] := MultiFoldList[f, {1,2}, {3,4,5}] (* for lack of a better name *)
Out[1]:= {1, 2, f[3,2,1], f[4,f[3,2,1],2], f[5,f[4,f[3,2,1],2],f[3,2,1]]}
```

I had something that did this, but I closed the notebook prior to saving it. So, if I rewrite it on my own, I'll post it.

**Edit**: as to why I am not using `RSolve`

or `MatrixPower`

to solve this. My specific problem is I'm performing an n-point Pade approximant to analytically continue a function I only know at a set number of points on the imaginary axis, {z_{i}}. Part of creating the approximant is to generate a set of coefficients, a_{i}, which is another recurrence relation, that are then fed into the final relationship

```
A[n+1]== A[n] + (z - z[[n]]) a[[n+1]] A[n-1]
```

which is not amenable to either `RSolve`

nor `MatrixPower`

, at least that I can see.