# Mapping which holds and passes previous result

When solving system of linear equations by Tridiagonal matrix algorithm in Haskell I met following problem.

We have three vectors: `a`, `b` and `c`, and we want to make a third vector `c'` which is a combination of them:

```c'[i] = c[i] / b[i], i = 0
c'[i] = c[i] / (b[i] - a[i] * c'[i-1]), 0 < i < n - 1
c'[i] = undefined, i = n - 1
```

Naive implementation of the formula above in Haskell is as follows:

```calcC' a b c = Data.Vector.generate n f
where
n = Data.Vector.length a
f i =
| i == 0 = c!0 / b!0
| i == n - 1 = 0
| otherwise = c!i / (b!i - a!i * f (i - 1))
```

It looks like this function `calcC'` has complexity O(n2) due to recurrence. But all we actualy need is to pass to inner function `f` one more parameter with previously generated value.

I wrote my own version of `generate` with complexity O(n) and helper function `mapP`:

```mapP f xs = mapP' xs Nothing
where
mapP' [] _ = []
mapP' (x:xs) xp = xn : mapP' xs (Just xn)
where
xn = f x xp

generateP n f = Data.Vector.fromList \$ mapP f [0 .. n-1]
```

As one can see, `mapP` acts like a standard `map`, but also passes to mapping function previously generated value or `Nothing` for first call.

My question: is there any pretty standard ways to do this in Haskell? Don't I reinvent the weel?

Thanks.

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There are two standard function called `mapAccumL` and `mapAccumR` that do precisely what you want.

``````mapAccumL :: (acc -> x -> (acc, y)) -> acc -> [x] -> (acc, [y])
mapAccumR :: (acc -> x -> (acc, y)) -> acc -> [x] -> (acc, [y])
``````

Basically, they behave like a combination of `fold` and `map`.

``````map   f   = snd . mapAccumL (\_ x -> (()   , f x) ()
foldl f b = fst . mapAccumL (\b x -> (f b x, () ) b
``````
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Thank you for the reply. After your comment I found prescanl function in Data.Vector library which seems to be a combination of my generateP and mapP. –  Andrey Mar 26 '11 at 13:42

If you use Data.Array, which is lazy, you can express the recurrence directly by referring to c' while defining c'.

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Following code seems to be the simplest implementation of formula above in my case:

```import qualified Data.Vector.Generic as V

calcC' a b c = V.postscanl' f 0.0 \$ V.zip3 a b c
where
f c' (a, b, c) = c / (b - a * c')
```

Thanks to the authors of `Vector` who added helpfull `postscanl'` method.

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