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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).

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For associative f, it can be parallelized and it is called a "scan". I couldn't find scan in the Repa documentation, though. – Heatsink Jun 27 '12 at 14:46
You may be able to do it with a repa stencil,… . But see also… – Don Stewart Jun 27 '12 at 14:57
@Heatsink Wouldn't a scan require a series as input? To me, this looks more like an unfold. – phg Jun 27 '12 at 15:00
Oh, it's not a scan. I misread the equation as 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
@Heatsink yes, that is exactly what I meant. Do you think is it possible to do that computation in Repa, especially when 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

I cannot see a Repa way of doing this. But there is for Vector: Data.Vector.iterateN builds the vector you want. Then Data.Array.Repa.fromUnboxed to convert it from Vector to Repa.

iterateN :: Int -> (a -> a) -> a -> Vector aSource

O(n) Apply function n times to value. Zeroth element is original value.

share|improve this answer
Thanks. This should be enough when doing 1D calculation. Probably I don't need to care about Repa. I just want something comparable to (non-optimized) C in terms of speed in Haskell. Can this be multidimensional? (Can a be another vector?) And if so, can it be parallelize? – tkf Jun 28 '12 at 12:26
Well, it depends what sort of multidimensional generalization you're asking about. In the 1D case, it's obviously impossible to parallelize, since the function itself is pretty inherently sequential. Can you be more specific about what the multidimensional generalization you're asking about would look like? – Louis Wasserman Jun 28 '12 at 14:45
Sure. Let's say a[i] is a vector (so a is a 2D array) and I want compute a[i] = M a[i-1] given an initial value a[0] and a matrix M, up to i=N-1. Using the notation I used for the title, its f(x) = M x where f is vectorized now. You can think of any kind of f, but basically it uses only the value of one step before. – tkf Jun 28 '12 at 16:57
Well, if you're in the lucky case of f being linear, there's several options for optimizing matrix multiplication, which I'd try first. But that depends on the form of M. Since I don't assume that your M is sparse (or is it?), you could look for something like this algorithm suitable for your kind of matrix. In general, though, every a[i][j] can depend on whole a[i-1], so I guess there's little you can parallelize for arbitrary matrices. – phg Jun 29 '12 at 8:01
You are right, I was not assuming sparse M. I should have clarified. I thought Repa is able to parallelize any kind of vector to vector computation, not only the linear one. Am I wrong? I know you cannot parallelize computation across steps, but I thought it might be possible to parallelize the computation within the step (e.g., vector to vector computation). – tkf Jun 29 '12 at 12:12

Edit: Actually, I think I misinterpreted the question. I'll leave my answer here, in case it's useful for someone else...

You can use traverse

Prelude Data.Array.Repa R> let x = fromListUnboxed (Z :. 10 :: DIM1) [1..10]
Prelude Data.Array.Repa R> R.computeUnboxedS $ R.traverse x (\ (Z :. i) -> (Z :. (i - 1))) (\f  (Z :. i) -> f (Z :. (i + 1)) - f (Z :. i))
AUnboxed (Z :. 9) (fromList [1.0,1.0,1.0,1.0,1.0,1.0,1.0,1.0,1.0])

Dissecting it:

    R.computeUnboxedS $                            -- force the vector to be "real"
    R.traverse x                                   -- traverse the vector
    (\ (Z :. i) -> (Z :. (i - 1)))                 -- function to get the shape of the result
    (\f (Z :. i) -> f (Z :. (i + 1)) - f (Z :. i)) -- actual "stencil"

Extending it to multi-dimensional array should be trivial.

share|improve this answer
You are calculating the result array based only on the source array. What I want to calculate is an array whose element depends on its one step earlier one. You might think the i in the title as the size of array. I meant the index. – tkf Jun 27 '12 at 22:38
What about using a combination of Data.Vector.Unboxed.scanl1' and Repa.toUnboxed? For example, cumsum would be: R.fromUnboxed (R.extent y) $ U.scanl1' (+) $ (R.toUnboxed y). [Ugly as hell, and probably not extendible to higher dimensions.] – lbolla Jun 28 '12 at 7:08
cumsum is still calculation from source array to target array. It depends on the earlier part of the source array, not the target. As Heatsink and phg mentioned in the above comments, unfold is what I need. I'd like to know how to do unfold in Repa (or any other array-oriented library in Haskell). – tkf Jun 28 '12 at 9:58

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