Is it possible to compute an array which depends on the past value(s) (i.e., lesser indexes), in Repa? Initial part(s) of the array (e.g., `a[0]`

) is given. (Note that I am using C-like notation to indicate an element of array; please don't confuse.)

I read the tutorial and quickly check the hackage but I could not find a function to do it.

(I guess doing this kind of computation in 1D array does not make sence in Repa because you can't parallelize it. But I think you can parallelize it in 2 or more dimensional case.)

**EDIT**:
Probably I should be more specific about what kind of `f`

I want to use. As there is no way to parallelize in the case `a[i]`

is a scalar, let's focus on the case `a[i]`

is a N dim vector. I don't need `a[i]`

to be higher dimensional (such as matrix) because you can "unroll" it to a vector. So, `f`

is a function which maps R^N to R^N.

Most of the case, it's like this:

```
b = M a[i-1]
a[i][j] = g(b)[j]
```

where `b`

is a N dim vector, `M`

is a N by N matrix (no assumption for sparseness), and `g`

is some nonlinear function. And I want to compute it for `i=1,..N-1`

given `a[0]`

, `g`

and `M`

. My hope is that there are some generic way to (1) parallelize this type of calculation and (2) make allocation of intermediate variables such as `b`

efficient (in C-like language, you can just reuse it, it would be nice if Repa or similar library can do it like a magic without breaking purity).

`f`

, it can be parallelized and it is called a "scan". en.wikipedia.org/wiki/Prefix_sum I couldn't find scan in the Repa documentation, though. – Heatsink Jun 27 '12 at 14:46`a[i] = f(a[i], a[i-1])`

. Actually, it's more like`take n $ iterate f z`

. – Heatsink Jun 27 '12 at 16:03`f`

is multi-dimensional? Also, I am afraid that using infinite list and take generate some kind of overhead comparing C-like language where you can allocate memory before the computation. I am hoping that Repa reduce such kind of overhead comparing to bare Haskell list. – tkf Jun 27 '12 at 17:59