This is pretty straightforward to translate:

```
module PNormalDist where
pnormaldist :: (Ord a, Floating a) => a -> Either String a
pnormaldist qn
| qn < 0 || 1 < qn = Left "Error: qn must be in [0,1]"
| qn == 0.5 = Right 0.0
| otherwise = Right $
let w3 = negate . log $ 4 * qn * (1 - qn)
b = [ 1.570796288, 0.03706987906, -0.8364353589e-3,
-0.2250947176e-3, 0.6841218299e-5, 0.5824238515e-5,
-0.104527497e-5, 0.8360937017e-7, -0.3231081277e-8,
0.3657763036e-10, 0.6936233982e-12]
w1 = sum . zipWith (*) b $ iterate (*w3) 1
in (signum $ qn - 0.5) * sqrt (w1 * w3)
```

First off, let's look at the ruby - it returns a value, but sometimes it prints an error message (when given an improper argument). This isn't very haskellish, so
let's have our return value be `Either String a`

- where we'll return a `Left String`

with an error message if given an improper argument, and a `Right a`

otherwise.

Now we check the two cases at the top:

`qn < 0 || 1 < qn = Left "Error: qn must be in [0,1]"`

- this is the error condition, when `qn`

is out of range.
`qn == 0.5 = Right 0.0`

- this is the ruby check `qn == 0.5 and return * 0.0`

Next up, we define `w1`

in the ruby code. But we redefine it a few lines later, which isn't very rubyish. The value that we store in `w1`

the first time
is used immediately in the definition of `w3`

, so why don't we skip storing it in `w1`

? We don't even need to do the `qn > 0.5 and w1 = 1.0 - w1`

step, because
we use the product `w1 * (1.0 - w1)`

in the definition of w3.

So we skip all that, and move straight to the definition `w3 = negate . log $ 4 * qn * (1 - qn)`

.

Next up is the definition of `b`

, which is a straight lift from the ruby code (ruby's syntax for an array literal is haskell's syntax for a list).

Here's the most tricky bit - defining the ultimate value of `w3`

. What the ruby code does in

```
w1 = b[0]
1.upto 10 do |i|
w1 += b[i] * w3**i;
end
```

Is what's called a fold - reducing a set of values (stored in a ruby array) into a single value. We can restate this more functionally (but still in ruby) using `Array#reduce`

:

```
w1 = b.zip(0..10).reduce(0) do |accum, (bval,i)|
accum + bval * w3^i
end
```

Note how I pushed `b[0]`

into the loop, using the identity `b[0] == b[0] * w3^0`

.

Now we could port this directly to haskell, but it's a bit ugly

```
w1 = foldl 0 (\accum (bval,i) -> accum + bval * w3**i) $ zip b [0..10]
```

Instead, I broke it up into several steps - first off, we don't really need `i`

, we just need the powers of `w3`

(starting at `w3^0 == 1`

), so
let's calculate those with `iterate (*w3) 1`

.

Then, rather than zipping those into pairs with the elements of b, we ultimately just need their products, so we can zip them into
the products of each pair using `zipWith (*) b`

.

Now our folding function is really easy - we just need to sum up the products, which we can do using `sum`

.

Lastly, we decide whether to return plus or minus `sqrt (w1 * w3)`

, according to whether `qn`

is greater or less than 0.5 (we
already know it's not equal). So rather than calculating the square root in two separate locations as in the ruby code,
I calculated it once, and multiplied it by `+1`

or `-1`

according to the sign of `qn - 0.5`

(`signum`

just returns the sign of a value).