These errors are the best kind, because they pinpoint where you have made a type error.

So let's do some manual type inference. Let's consider the expression:

```
map (\y -> (if (getAvg x > y) then 1 else 0)) x
```

There are a few constraints we know off the bat:

```
map :: (a -> b) -> [a] -> [b] -- from definition
(>) :: Num a => a -> a -> Bool -- from definition
getAvg :: [Integer] -> Double -- from type declaration
1, 0 :: Num a => a -- that's how Haskell works
x :: [Integer] -- from type declaration of smallerThanAVG
```

Now let's look at the larger expressions.

```
expr1 = getAvg x
expr2 = (expr1 > y)
expr3 = (if expr2 then 1 else 0)
expr4 = (\y -> expr3)
expr5 = map expr4 x
```

Now let's work backwards. `expr5`

is the same as the RHS of `smallerThanAVG`

, so that means it has the same result type as what you've declared.

```
expr5 :: Integer -- wrong
```

However, this doesn't match our other constraint: the result of `map`

must be `[b]`

for some `b`

. `Integer`

is definitely *not* a list (although if you get facetious, it could be coerced into a list of bits). You probably meant to `sum`

that list up.

```
expr6 = sum expr5
sum :: Num a => [a] -> a
```

Now let's work forwards.

```
expr1 :: Double -- result type of getAvg
y :: Double -- (>) in expr2 requires both inputs to have the same type
expr4 :: (Integer -> [a]) -- because for `map foo xs` (expr5)
-- where xs :: [a], foo must accept input a
y :: Integer -- y must have the input type of expr4
```

Herein lies the conflict: `y`

cannot be both a `Double`

and an `Integer`

. I could equivalently restate this as: `x`

cannot be both a `[Double]`

and `[Integer]`

, which is what the compiler is saying. So tl;dr, the kicker is that `(>)`

doesn't compare different types of `Num`

s. The meme for this sort of problem is: "needs more `fromIntegral`

".

```
(getAvg x > fromIntegral y)
```