A bug breaks this in current GHCs. Once the fix is merged in, this should work fine. In the meantime, the other answer can tide you over.

First, define

```
data Elem :: k -> [k] -> Type where
Here :: Elem x (x : xs)
There :: Elem x xs -> Elem x (y : xs)
```

An `Elem x xs`

tells you where to find an `x`

in an `xs`

. Also, here's an existential wrapper:

```
data EntryOfVal v kvs = forall k. EntryOfVal (Elem (k, v) kvs)
-- to be clear, this is the type constructor (,) :: Type -> Type -> Type
type family EntryOfValKey (eov :: EntryOfVal v kvs) :: Type where
EntryOfValKey ('EntryOfVal (_ :: Elem (k, v) kvs)) = k
type family GetEntryOfVal (eov :: EntryOfVal v kvs) :: Elem (EntryOfValKey eov, v) kvs where
GetEntryOfVal ('EntryOfVal e) = e
```

If you have an `Elem`

at the type level, you may materialize it

```
class MElem (e :: Elem (x :: k) xs) where
mElem :: Elem x xs
instance MElem Here where
mElem = Here
instance MElem e => MElem (There e) where
mElem = There (mElem @_ @_ @_ @e)
```

Similarly, you may materialize an `EntryOfVal`

```
type MEntryOfVal eov = MElem (GetEntryOfVal eov) -- can be a proper constraint synonym
mEntryOfVal :: forall v kvs (eov :: EntryOfVal v kvs).
MEntryOfVal eov =>
EntryOfVal v kvs
mEntryOfVal = EntryOfVal (mElem @_ @_ @_ @(GetEntryOfVal eov))
```

If a type is an element of a list of types, then you may extract a value of that type from an `HList`

of that list of types:

```
indexH :: Elem t ts -> HList ts -> t
indexH Here (HCons x _) = x
indexH (There i) (HCons _ xs) = indexH i xs
```

(I feel the need to point out how fundamentally important `indexH`

is to `HList`

. For one, `HList ts`

is isomorphic to its indexer `forall t. Elem t ts -> t`

. Also, `indexH`

has a dual, `injS :: Elem t ts -> t -> Sum ts`

for suitable `Sum`

.)

Meanwhile, up on the type level, this function can give you the first possible `EntryOfVal`

given a value type and a list:

```
type family FirstEntryOfVal (v :: Type) (kvs :: [Type]) :: EntryOfVal v kvs where
FirstEntryOfVal v ((k, v) : _) = 'EntryOfVal Here
FirstEntryOfVal v (_ : kvs) = 'EntryOfVal (There (GetEntryOfVal (FirstEntryOfVal v kvs)))
```

The reason for separating the materialization classes from `FirstEntryOfVal`

is because the classes are reusable. You can easily write new type families that return `Elem`

s or `EntryOfVal`

s and materialize them. Merging them together into one monolithic class is messy, and now you have to rewrite the "logic" (not that there is much) of `MElem`

every time instead of reusing it. My approach does, however, give a higher up-front cost. However, the code required is entirely mechanical, so it is conceivable that a TH library could write it for you. I don't know a library that *can* handle this, but `singletons`

plans to.

Now, this function can get you a value given a `EntryOfVal`

proof:

```
indexHVal :: forall v kvs. EntryOfVal v kvs -> HList kvs -> v
indexHVal (EntryOfVal e) = snd . indexH e
```

And now GHC can do some thinking for you:

```
indexHFirstVal :: forall v kvs. MEntryOfVal (FirstEntryOfVal v kvs) =>
HList kvs -> v
indexHFirstVal = indexHVal (mEntryOfVal @_ @_ @(FirstEntryOfVal v kvs))
```

Once you have the value, you need to find the keys. For efficiency (O(n) vs. O(n^2), I think) reasons and for my sanity, we won't make a mirror of `EntryOfVal`

, but use a slightly different type. I'll just give the boilerplate without explanation, now

```
-- for maximal reuse:
-- data All :: (k -> Type) -> [k] -> Type
-- where an All f xs contains an f x for every x in xs
-- plus a suitable data type to recover EntriesOfKey from All
-- not done here mostly because All f xs's materialization
-- depends on f's, so we'd need more machinery to generically
-- do that
-- in an environment where the infrastructure already exists
-- (e.g. in singletons, where our materializers decompose as a
-- composition of SingI materialization and SingKind demotion)
-- using All would be feasible
data EntriesOfKey :: Type -> [Type] -> Type where
Nowhere :: EntriesOfKey k '[]
HereAndThere :: EntriesOfKey k kvs -> EntriesOfKey k ((k, v) : kvs)
JustThere :: EntriesOfKey k kvs -> EntriesOfKey k (kv : kvs)
class MEntriesOfKey (esk :: EntriesOfKey k kvs) where
mEntriesOfKey :: EntriesOfKey k kvs
instance MEntriesOfKey Nowhere where
mEntriesOfKey = Nowhere
instance MEntriesOfKey e => MEntriesOfKey (HereAndThere e) where
mEntriesOfKey = HereAndThere (mEntriesOfKey @_ @_ @e)
instance MEntriesOfKey e => MEntriesOfKey (JustThere e) where
mEntriesOfKey = JustThere (mEntriesOfKey @_ @_ @e)
```

The logic:

```
type family AllEntriesOfKey (k :: Type) (kvs :: [Type]) :: EntriesOfKey k kvs where
AllEntriesOfKey _ '[] = Nowhere
AllEntriesOfKey k ((k, _) : kvs) = HereAndThere (AllEntriesOfKey k kvs)
AllEntriesOfKey k (_ : kvs) = JustThere (AllEntriesOfKey k kvs)
```

The actual value manipulation

```
updateHKeys :: EntriesOfKey k kvs -> (k -> k) -> HList kvs -> HList kvs
updateHKeys Nowhere f HNil = HNil
updateHKeys (HereAndThere is) f (HCons (k, v) kvs) = HCons (f k, v) (updateHKeys is f kvs)
updateHKeys (JustThere is) f (HCons kv kvs) = HCons kv (updateHKeys is f kvs)
```

Get GHC to think some more

```
updateHAllKeys :: forall k kvs. MEntriesOfKey (AllEntriesOfKey k kvs) =>
(k -> k) -> HList kvs -> HList kvs
updateHAllKeys = updateHKeys (mEntriesOfKey @_ @_ @(AllEntriesOfKey k kvs))
```

All together now:

```
replaceAll :: forall t kvs.
(MEntryOfVal (FirstEntryOfVal t kvs), MEntriesOfKey (AllEntriesOfKey t kvs)) =>
HList kvs -> HList kvs
replaceAll xs = updateHAllKeys (const $ indexHFirstVal @t xs) xs
```

`typerep-map`

that contains`Map`

from types to values. And it's possible to apply function to values of given type with`typerep-map`

(though it won't quite work for your example). But the idea is that you don't needpath-dependent-typesfor this. It's enough to have RTTI (runtime type information). – Shersh Aug 21 '18 at 9:11`a`

from this HList. I would like to apply the following algorithm. If I have find a function whose output type is`a`

then I have 2 cases. Either this is a 0-ary function then I get a value of type`a`

, done. Or this is a function of n arguments each of those I might be able to get from my HList by recursively running the same algorithm. If nothing matches in terms of types then I want to get a type error – Eric Aug 21 '18 at 9:50