I am using Numeric.Integration.TanhSinh for numerical integration in Haskell. This defines a function

```
parTrap :: (Double -> Double) -> Double -> Double -> [Result]
```

where the first argument is the 1-dimensional function to be integrated, then upper and lower bounds. I have a wrapper which transforms this function as

```
ttrap f xmin xmax = (ans, err)
where
res = absolute 1e-6 $ parTrap f xmin xmax
ans = result res
err = errorEstimate res
```

To integrate a 2-dimensional function, I can use

```
ttrap2 f y1 y2 g1 g2 = ttrap h y1 y2 -- f ylower yupper (fn for x lower) (fn for x upper)
where
h y = fst $ ttrap (flip f y) (g1 y) (g2 y)
ttrap2_fixed f y1 y2 x1 x2 = ttrap2 f y1 y2 (const x1) (const x2)
```

The idea of `ttrap2_fixed`

is that I can now do a double integral where the function is (Double -> Double -> Double), and bounds are `y1 y2 x1 x2`

.

Using this pattern, I can define higher order integration functions

```
ttrap3_fixed :: (Double -> Double -> Double -> Double) -> Double -> Double -> Double -> Double -> Double -> Double -> Double
ttrap3_fixed f z1 z2 y1 y2 x1 x2 = fst $ ttrap h z1 z2
where
h z = fst $ ttrap2_fixed (f z) x1 x2 y1 y2
ttrap4_fixed :: (Double -> Double -> Double -> Double -> Double) -> Double -> Double -> Double -> Double -> Double -> Double -> Double -> Double -> Double
ttrap4_fixed f w1 w2 z1 z2 y1 y2 x1 x2 = fst $ ttrap h w1 w2
where
h w = ttrap3_fixed (f w) z1 z2 x1 x2 y1 y2
ttrap5_fixed :: (Double -> Double -> Double -> Double -> Double -> Double) -> Double -> Double -> Double -> Double -> Double -> Double -> Double -> Double -> Double -> Double -> Double
ttrap5_fixed f u1 u2 w1 w2 z1 z2 y1 y2 x1 x2 = fst $ ttrap h u1 u2
where
h u = ttrap4_fixed (f u) w1 w2 z1 z2 x1 x2 y1 y2
```

However, I would like to integrate a function of type

```
f :: [Double] -> Double
```

with the idea being that the dimensionality of the function can vary within the program. Ideally, I would like a function with type

```
int_listfn :: ([Double] -> Double) -> [(Double, Double)] -> Double
```

where I can integrate the multidimensional function over a list of tuples of bounds. As part of this, it seems like I need to use something like continuation passing style to construct the integrator function, but this is where I am getting stuck. Thanks in advance.

An example of a `f`

that I would like to integrate would be something like

```
> let f [x,y,z] = x**3.0 * sin(y) + (1.0/z)
```

Consider bounds

```
> let bounds = [(1.0,2.0),(2.0,4.0), (0.0,3.0)]
> int_listfn f bounds
```

This should be equivalent to calculating

EDIT: Adding another example function

```
f1 :: Double -> Double
f1 x = 1.0 * x
fn_maker :: [Double -> Double] -> ([Double] -> Double)
fn_maker inlist = myfn
where
myfn xlist = product $ zipWith (\f x -> f x) inlist xlist
m = 4
f_list = fn_maker (replicate f1 m)
```

`f_list`

has type `[Double] -> Double`

and is equivalent to `f x y z w = x * y * z * w`

. I thought that the type `[Double] -> Double`

would be appropriate because the dimensionality of the function, `m`

, is a parameter. Perhaps I need to change the design.

**List function to curried functions**, @fizruk I have been using this in my code and seems to work, although I need to keep track of which function to call based on the size of the bounds list.

```
static_1 :: ([Double] -> Double) -> (Double -> Double)
static_1 f = f'
where
f' x = f [x]
static_2 :: ([Double] -> Double) -> (Double -> Double -> Double)
static_2 f = f'
where
f' x y = f [x,y]
static_3 :: ([Double] -> Double) -> (Double -> Double -> Double -> Double)
static_3 f = f'
where
f' x y z = f [x,y,z]
static_4 :: ([Double] -> Double) -> (Double -> Double -> Double -> Double -> Double)
static_4 f = f'
where
f' x y z w = f [x,y,z,w]
static_5 :: ([Double] -> Double) -> (Double -> Double -> Double -> Double -> Double -> Double)
static_5 f = f'
where
f' x y z w u = f [x,y,z,w,u]
int_listfn :: ([Double] -> Double) -> [(Double, Double)] -> Double
int_listfn f bounds
| f_dim == 1 = fst $ ttrap (static_1 f) (fst (bounds !! 0)) (snd (bounds !! 0))
| f_dim == 2 = fst $ ttrap2_fixed (static_2 f) (fst (bounds !! 0)) (snd (bounds !! 0)) (fst (bounds !! 1)) (snd (bounds !! 1))
| f_dim == 3 = ttrap3_fixed (static_3 f) (fst (bounds !! 0)) (snd (bounds !! 0)) (fst (bounds !! 1)) (snd (bounds !! 1)) (fst (bounds !! 2)) (snd (bounds !! 2))
| f_dim == 4 = ttrap4_fixed (static_4 f) (fst (bounds !! 0)) (snd (bounds !! 0)) (fst (bounds !! 1)) (snd (bounds !! 1)) (fst (bounds !! 2)) (snd (bounds !! 2)) (fst (bounds !! 3)) (snd (bounds !! 3))
| f_dim == 5 = ttrap5_fixed (static_5 f) (fst (bounds !! 0)) (snd (bounds !! 0)) (fst (bounds !! 1)) (snd (bounds !! 1)) (fst (bounds !! 2)) (snd (bounds !! 2)) (fst (bounds !! 3)) (snd (bounds !! 3)) (fst (bounds !! 3)) (snd (bounds !! 3))
| otherwise = error "Unsupported integral size"
where
f_dim = length bounds
```

`f :: Intergrable r => r`

with instances for`Double`

and`Intergrable r => Double -> r`

? I mean the similar trick to that exploited to make`printf`

polyvariadic? – fizruk May 19 '14 at 19:17`f_list x y z w = product (map f1 [x, y, z, w])`

? Or`product (zipWith ($) (repeat f1) [x, y, z, w])`

? Both definition state precisely which number of arguments they take, but are "operating on list"`[x, y, z, w]`

. – fizruk May 19 '14 at 21:21`m`

is a parameter in the code that is set, say as a command line argument by the user, then I would need definitions for every possible value of`m`

, up to some`mMax`

, right? I was hoping to avoid that if possible. – stevejb May 19 '14 at 21:27`[Double] -> Double`

functions. – fizruk May 19 '14 at 22:15