Actually, if you incorporate the way `p_sin`

is unsafe from that answer, it depends on `p_sin`

*not* being a mathematical function, at least not one from numbers to numbers -- it depends on giving different answers when the memory the same pointer points to is different. So, mathematically speaking, there is *something* different between the two calls; with a formal model of pointers we might be able to tell. E.g.

```
type Ptr = Int
type Heap = [Double]
p_sin :: Heap -> Ptr -> Double
```

and then the C function would be equivalent to

```
p_sin h p = sin (h !! p)
```

The reason the results would differ is because of a different `Heap`

argument, which is unnamed but implicit in the C definition.

If `p_sin`

used temporary memory internally, but did not depend on the state of memory through its interface, e.g.

```
double p_sin(double x) {
double* y = (double*)malloc(sizeof(double));
*y = sin(x);
x = *y;
free(y);
return x;
}
```

then we do have an actual mathematical function `Double -> Double`

, and we can

```
foreign import ccall safe "p_sin"
p_sin :: Double -> Double
```

and we're be fine. Pointers in the interface are killing the purity here, not C functions.

More practically, let's say you have a C matrix multiplication function implemented with pointers, since that's how you model arrays in C. In this case you'd probably expand the abstraction boundary, so there would be a few unsafe things going on in your program, but they would all be hidden from the module user. In this case, I recommend annotating everything unsafe with `IO`

in your implementation, and then `unsafePerformIO`

ing right before you give it to the module user. This minimizes the surface area of impurity.

```
module Matrix
-- only export things guaranteed to interact together purely
(Matrix, makeMatrix, multMatrix)
where
newtype Matrix = Matrix (Ptr Double)
makeMatrix :: [[Double]] -> Matrix
makeMatrix = unsafePerformIO $ ...
foreign import ccall safe "multMatrix"
multMatrix_ :: Ptr Double -> IO (Ptr Double)
multMatrix :: Matrix -> Matrix
multMatrix (Matrix p) = unsafePerformIO $ multMatrix_ p
```

etc.