# Is there a monad that doesn't have a corresponding monad transformer (except IO)?

So far, every monad (that can be represented as a data type) that I have encountered had a corresponding monad transformer, or could have one. Is there such a monad that can't have one? Or do all monads have a corresponding transformer?

By a transformer `t` corresponding to monad `m` I mean that `t Identity` is isomorphic to `m`. And of course that it satisfies the monad transformer laws and that `t n` is a monad for any monad `n`.

I'd like to see either a proof (ideally a constructive one) that every monad has one, or an example of a particular monad that doesn't have one (with a proof). I'm interested in both more Haskell-oriented answers, as well as (category) theoretical ones.

As a follow-up question, is there a monad `m` that has two distinct transformers `t1` and `t2`? That is, `t1 Identity` is isomorphic to `t2 Identity` and to `m`, but there is a monad `n` such that `t1 n` is not isomorphic to `t2 n`.

(`IO` and `ST` have a special semantics so I don't take them into account here and let's disregard them completely. Let's focus only on "pure" monads that can be constructed using data types.)

• `ST` is the other obvious example, but it also violates your "pure" monad restriction. – Ganesh Sittampalam Jul 1 '14 at 17:23
• @bennofs Yes, but not just the monad transformer laws, it could be that `T` satisfies them, but for some monad `n` the type `T n` fails to be a monad. For example `ListT` fails to satisfy monad laws for just some monads (non-commutative ones), however, there is another, correct transformer for `[]`. – Petr Pudlák Jul 1 '14 at 17:32
• The list of "this is obviously IO" exceptions is basically infinite. There's `STM`, for instance. But there's also every single custom monad that works over IO intrinsically. Lots of libraries provide such things. – Carl Jul 1 '14 at 18:24
• @leftaroundabout `Cont` is almost the opposite: It's so easy to turn into a transformer that the methods of the `Monad` instance for `ContT m` don't even need the `Monad` instance for `m`. – Ørjan Johansen Jul 2 '14 at 1:51
• Any Monad that can be expressed as a Free monad for some functor (which is almost all of them: stackoverflow.com/questions/14641864/…) should also get the free monad transformer. – Cirdec Jul 2 '14 at 4:43

I'm with @Rhymoid on this one, I believe all Monads have two (!!) transformers. My construction is a bit different, and far less complete. I'd like to be able to take this sketch into a proof, but I think I'm either missing the skills/intuition and/or it may be quite involved.

Due to Kleisli, every monad (`m`) can be decomposed into two functors `F_k` and `G_k` such that `F_k` is left adjoint to `G_k` and that `m` is isomorphic to `G_k * F_k` (here `*` is functor composition). Also, because of the adjunction, `F_k * G_k` forms a comonad.

I claim that `t_mk` defined such that `t_mk n = G_k * n * F_k` is a monad transformer. Clearly, `t_mk Id = G_k * Id * F_k = G_k * F_k = m`. Defining `return` for this functor is not difficult since `F_k` is a "pointed" functor, and defining `join` should be possible since `extract` from the comonad `F_k * G_k` can be used to reduce values of type `(t_mk n * t_mk n) a = (G_k * n * F_k * G_k * n * F_k) a` to values of type `G_k * n * n * F_k`, which is then further reduces via `join` from `n`.

We do have to be a bit careful since `F_k` and `G_k` are not endofunctors on Hask. So, they are not instances of the standard `Functor` typeclass, and also are not directly composable with `n` as shown above. Instead we have to "project" `n` into the Kleisli category before composition, but I believe `return` from `m` provides that "projection".

I believe you can also do this with the Eilenberg-Moore monad decomposition, giving `m = G_em * F_em`, `tm_em n = G_em * n * F_em`, and similar constructions for `lift`, `return`, and `join` with a similar dependency on `extract` from the comonad `F_em * G_em`.

• A very nice idea. Could you perhaps add an example, deriving some well-known monad transformer this way? – Petr Pudlák Jul 20 '14 at 6:35
• stackoverflow.com/a/4702513/2008899 builds the State monad from an adjunction. If instead you were trying to build StateT from that adjunction, there are at least 3 possible ways to compose the functors with different corresponding definitions of StateT s IO: `StateT s IO a ~ s -> (IO a, s)` (r * w * m), `StateT s IO a ~ IO (s -> (a, s))` (m * r * w), and `StateT s IO a ~ s -> IO (a, s)` (r * m * w). The last, correct, construction is how I propose to build a transformer from an adjunction. – Boyd Stephen Smith Jr. Jul 20 '14 at 21:08
• Granted bounty to this answer, since it's the only rigorous answer that hasn't been disproven. Still, more elaboration would be awesome :) – user824425 Jul 21 '14 at 21:22
• I got some time to try to elaborate on your answer. All looks good, but interestingly so far I haven't been able to implement `lift` from `MonadTrans`. Any ideas? – Petr Pudlák Mar 31 '15 at 18:37
• Ok, I hadn't ever heard the term "monoidal operation" before. (I thought you meant the product of the monad as a monoid in the category of endofunctors.) So nevermind. Still, I don't see how your "projection" would work. Why would any functor need to work on endofunctions of the Kleisli category? – Turion Jun 17 '16 at 10:34

Here's a hand-wavy I'm-not-quite-sure answer.

Monads can be thought of as the interface of imperative languages. `return` is how you inject a pure value into the language, and `>>=` is how you splice pieces of the language together. The Monad laws ensure that "refactoring" pieces of the language works the way you would expect. Any additional actions provided by a monad can be thought of as its "operations."

Monad Transformers are one way to approach the "extensible effects" problem. If we have a Monad Transformer `t` which transforms a Monad `m`, then we could say that the language `m` is being extended with additional operations available via `t`. The `Identity` monad is the language with no effects/operations, so applying `t` to `Identity` will just get you a language with only the operations provided by `t`.

So if we think of Monads in terms of the "inject, splice, and other operations" model, then we can just reformulate them using the Free Monad Transformer. Even the IO monad could be turned into a transformer this way. The only catch is that you probably want some way to peel that layer off the transformer stack at some point, and the only sensible way to do it is if you have `IO` at the bottom of the stack so that you can just perform the operations there.

Update: Statements 1 and 2 below are most likely incorrect; I think I found monad transformers for those cases. I have not yet finished the required calculations but they look promising. Statements 3 and 4 still stand. I added Statement 5 to show an example of a monad with two distinct transformers.

The transformer for `Either a (z -> a)` is (most likely) `n (Either a (z -> m a)`, where `m` is an arbitrary foreign monad. The transformer for `(a -> n p) -> n a` is (most likely) `(a -> t m p) -> t m a` where `t m` is the transformer for the monad `n`.

1. I think I found at least one counterexample: a simple and explicit monad that has no simple and explicit monad transformer.

The monad type constructor `L` for this counterexample is defined by

``````  type L z a  = Either a (z -> a)
``````

The intent of this monad is to embellish the ordinary reader monad `z -> a` with an explicit `pure` value (`Left x`). The ordinary reader monad's `pure` value is a constant function `pure x = _ -> x`. However, if we are given a value of type `z -> a`, we will not be able to determine whether this value is a constant function. With `L z a`, the `pure` value is represented explicitly as `Left x`. Users can now pattern-match on `L z a` and determine whether a given monadic value is pure or has an effect. Other than that, the monad `L z` does exactly the same thing as the reader monad.

``````  instance Monad (L z) where
return x = Left x
(Left x) >>= f = f x
(Right q) >>= f = Right(join merged) where
join :: (z -> z -> r) -> z -> r
join f x = f x x -- the standard `join` for Reader monad
merged :: z -> z -> r
merged = merge . f . q -- `f . q` is the `fmap` of the Reader monad
merge :: Either a (z -> a) -> z -> a
merge (Left x) _ = x
merge (Right p) z = p z
``````

This monad `L z` is a specific case of a more general construction, `(Monad m) => Monad (L m)` where `L m a = Either a (m a)`. This construction embellishes a given monad `m` by adding an explicit `pure` value (`Left x`), so that users can now pattern-match on `L m` to decide whether the value is pure. In all other ways, `L m` represents the same computational effect as the monad `m`.

The monad instance for `L m` is almost the same as for the example above, except the `join` and `fmap` of the monad `m` need to be used, and the helper function `merge` is defined by

``````    merge :: Either a (m a) -> m a
merge (Left x) = return @m x
merge (Right p) = p
``````

I checked that the laws of the monad hold for `L m` with an arbitrary monad `m`.

So, I think `L m` has no monad transformer, either for general `m` or even for a simple monad `m = Reader`. It suffices to consider `L z` as defined above; even that simple monad does not seem to have a transformer.

The (heuristic) reason for the non-existence of a monad transformer is that this monad has a `Reader` inside an `Either`. The `Either` monad transformer needs its base monad to be composed inside the foreign monad, `EitherT e m a = m (Either e a)`, because the monad transformer operates using the traversal. It appears that any monad that contains an `Either` in its data type will need a traversal for the monad transformer to work, and so there must be an "inside" composition in the transformer. However, the `Reader` monad transformer needs its base monad to be composed outside the foreign monad, `ReaderT r m a = r -> m a`. The monad `L` is a composition of a data type that demands a composed-inside transformer and a monad that demands a composed-outside transformer, and the second monad is inside the first one, which is impossible to reconcile. No matter how we try to define an L-transformer `LT`, it seems that we cannot satisfy the laws of the monad transformers.

One possibility of defining a type constructor `LT` would be `LT z m a = Either a (z -> m a)`. The result is a lawful monad, but the morphism `m a -> LT z m a` does not preserve `m`'s `return` because `return x` is mapped into a `Right (\z -> return x)`, which is not the `L`'s `return` (always a `Left x`).

Another possibility is `LT z m a = z -> Either a (m a)`. The result is a monad, but again `m`'s `return` is mapped into `\_ -> Right (...)` instead of the `Left (...)` as required for the monad `z -> Either a (m a)`.

Yet another possibility of combining the available type constructors is `LT z m a = Either a (m (z -> a) )`, but this is not a monad for arbitrary monad `m`.

I am not sure how to prove rigorously that `L` has no monad transformer, but no combination of the type constructors `Either`, `->`, and `m` seems to work correctly.

So, the monad `L z` and generally the monads of the form `L m` seem to have no simple and easy to use monad transformer that would be an explicit type constructor (a combination of `Either`, `->` and `m`).

1. Another example of a monad that does not seem to have an explicit monad transformer:

`type S a = (a -> Bool) -> Maybe a`

This monad appeared in the context of "search monads" here. The paper by Jules Hedges also mentions the search monad, and more generally, "selection" monads of the form

`````` type Sq n q a = (a -> n q) -> n a
``````

for a given monad `n` and a fixed type `q`. The search monad above is a particular case of the selection monad with `n a = Maybe a` and `q = ()`. However, the paper by Hedges (in my view incorrectly) claims that `Sq` is a monad transformer for the monad `(a -> q) -> a`.

My opinion is that the monad `(a -> q) -> a` has the monad transformer `(m a -> q) -> m a` of the "composed outside" type. This is related to the property of "rigidity" explored in the question Is this property of a functor stronger than a monad? Namely, `(a -> q) -> a` is a rigid monad, and all rigid monads have monad transformers of the "composed-outside" type.

However, `(a -> n q) -> n a` is not rigid unless the monad `n` is rigid. Since not all monads are rigid (e.g. `Maybe` and `Cont` are not rigid), the monad `(a -> n q) -> n a` will not have a monad transformer of the "composed-outside" type, `(m a -> n q) -> n (m a)`. Neither will it have a "composed-inside" transformer, `m((a -> n q) -> n a)` - this is not a monad for arbitrary monad `m`; take `m = Maybe` for a counterexample. The type `(a -> m (n q)) -> m (n a)` is similarly not a monad for arbitrary monads `m` and `n`. The type `m(a -> n q) -> n a` is a monad for any `m` but does not admit a lifting `m a -> m (a -> n q) -> n a` because we cannot compute a value of `n a` given only some values wrapped into an arbitrary monad `m`.

Both `S` and `Sq` are lawful monads (I checked it manually) but neither of them seems to have a lawful monad transformer.

Here is a heuristic argument for the non-existence of the monad transformer. If there were a data type definition for the monad transformer of `(a -> n q) -> n a` that works for all monads `n`, that data type definition would have yielded the "composed-outside" transformer for rigid `n` and some other transformer for non-rigid `n`. But this kind of choice is impossible for a type expression that uses `n` naturally and parametrically (i.e. as an opaque type constructor with a monad instance).

1. Generally, transformed monads don't themselves automatically possess a monad transformer. That is, once we take some foreign monad `m` and apply some monad transformer `t` to it, we obtain a new monad `t m`, and this monad doesn't have a transformer: given a new foreign monad `n`, we don't know how to transform `n` with the monad `t m`. If we know the transformer `mt` for the monad `m`, we can first transform `n` with `mt` and then transform the result with `t`. But if we don't have a transformer for the monad `m`, we are stuck: there is no construction that creates a transformer for the monad `t m` out of the knowledge of `t` alone and works for arbitrary foreign monads `m`.

2. @JamesCandy's answer suggests that for any monad (including `IO`?!), one can write a (general but complicated) type expression that represents the corresponding monad transformer. Namely, you first need to Church-encode your monad type, which makes the type look like a continuation monad, and then define its monad transformer as if for the continuation monad. But I think this is incorrect - it does not give a recipe for producing a monad transformer in general.

Taking the Church encoding of a type `a` means writing down the type

`````` type ca = forall r. (a -> r) -> r
``````

This type `ca` is completely isomorphic to `a` by Yoneda's lemma. So far we have achieved nothing other than made the type a lot more complicated by introducing a quantified type parameter `forall r`.

Now let's Church-encode a base monad `L`:

`````` type CL a = forall r. (L a -> r) -> r
``````

Again, we have achieved nothing so far, since `CL a` is fully equivalent to `L a`.

Now pretend for a second that `CL a` a continuation monad (which it isn't!), and write the monad transformer as if it were a continuation monad transformer, by replacing the result type `r` through `m r`:

`````` type TCL m a = forall r. (L a -> m r) -> m r
``````

This is claimed to be the "Church-encoded monad transformer" for `L`. But this seems to be incorrect. We need to check the properties:

• `TCL m` is a lawful monad for any foreign monad `m` and for any base monad `L`
• `m a -> TCL m a` is a lawful monadic morphism

The second property holds, but I believe the first property fails, - in other words, `TCL m` is not a monad for an arbitrary monad `m`. Perhaps some monads `m` admit this but others do not. I was not able to find a general monad instance for `TCL m` corresponding to an arbitrary base monad `L`.

Another way to argue that `TCL m` is not in general a monad is to note that `forall r. (a -> m r) -> m r` is indeed a monad for any type constructor `m`. Denote this monad by `CM`. Now, `TCL m a = CM (L a)`. If `TCL m` were a monad, it would imply that `CM` can be composed with any monad `L` and yields a lawful monad `CM (L a)`. However, it is highly unlikely that a nontrivial monad `CM` (in particular, one that is not equivalent to `Reader`) will compose with all monads `L`. Monads usually do not compose without stringent further constraints.

A specific example where this does not work is for reader monads. Consider `L a = r -> a` and `m a = s -> a` where `r` and `s` are some fixed types. Now, we would like to consider the "Church-encoded monad transformer" `forall t. (L a -> m t) -> m t`. We can simplify this type expression using the Yoneda lemma,

`````` forall t. (x -> t) -> Q t  = Q x
``````

(for any functor `Q`) and obtain

`````` forall t. (L a -> s -> t) -> s -> t
= forall t. ((L a, s) -> t) -> s -> t
= s -> (L a, s)
= s -> (r -> a, s)
``````

So this is the type expression for `TCL m a` in this case. If `TCL` were a monad transformer then `P a = s -> (r -> a, s)` would be a monad. But one can check explicitly that this `P` is actually not a monad (one cannot implement `return` and `bind` that satisfy the laws).

Even if this worked (i.e. assuming that I made a mistake in claiming that `TCL m` is in general not a monad), this construction has certain disadvantages:

• It is not functorial (i.e. not covariant) with respect to the foreign monad `m`, so we cannot do things like interpret a transformed free monad into another monad, or merge two monad transformers as explained here Is there a principled way to compose two monad transformers if they are of different type, but their underlying monad is of the same type?
• The presence of a `forall r` makes the type quite complicated to reason about and may lead to performance degradation (see the "Church encoding considered harmful" paper) and stack overflows (since Church encoding is usually not stack-safe)
• The Church-encoded monad transformer for an identity base monad (`L = Id`) does not yield the unmodified foreign monad: `T m a = forall r. (a -> m r) -> m r` and this is not the same as `m a`. In fact it's quite difficult to figure out what that monad is, given a monad `m`.

As an example showing why `forall r` makes reasoning complicated, consider the foreign monad `m a = Maybe a` and try to understand what the type `forall r. (a -> Maybe r) -> Maybe r` actually means. I was not able to simplify this type or to find a good explanation about what this type does, i.e. what kind of "effect" it represents (since it's a monad, it must represent some kind of "effect") and how one would use such a type.

• The Church-encoded monad transformer is not equivalent to the standard well-known monad transformers such as `ReaderT`, `WriterT`, `EitherT`, `StateT` and so on.

It is not clear how many other monad transformers exist and in what cases one would use one or another transformer.

1. One of the questions in the post is to find an explicit example of a monad `m` that has two transformers `t1` and `t2` such that for some foreign monad `n`, the monads `t1 n` and `t2 n` are not equivalent.

I believe that the `Search` monad provides such an example.

`````` type Search a = (a -> p) -> a
``````

where `p` is a fixed type.

The transformers are

`````` type SearchT1 n a = (a -> n p) -> n a
type SearchT2 n a = (n a -> p) -> n a
``````

I checked that both `SearchT1 n` and `SearchT2 n` are lawful monads for any monad `n`. We have liftings `n a -> SearchT1 n a` and `n a -> SearchT2 n a` that work by returning constant functions (just return `n a` as given, ignoring the argument). We have `SearchT1 Identity` and `SearchT2 Identity` obviously equivalent to `Search`.

The big difference between `SearchT1` and `SearchT2` is that `SearchT1` is not functorial in `n`, while `SearchT2` is. This may have implications for "running" ("interpreting") the transformed monad, since normally we would like to be able to lift an interpreter `n a -> n' a` into a "runner" `SearchT n a -> SearchT n' a`. This is possibly only with `SearchT2`.

A similar deficiency is present in the standard monad transformers for the continuation monad and the codensity monad: they are not functorial in the foreign monad.

• @WillNess thank you, I corrected the mistake. It should have been `Right(\z -> merge (f (q z)))`. – winitzki Feb 13 at 23:38

My solution exploits the logical structure of Haskell terms. Everyone knows that a function in Haskell with return type t can be turned into a monadic function with return type (Monad m) => m t. Therefore if the "bind" function could have its program text "monadified" appropriately, the result would be a monad transformer.

The sticking point is that there is no reason why the "monadification" of the "bind" operator should satisfy the laws, particularly associativity. This is where cut-elimination comes in. The cut elimination theorem has the effect on a program text of inlining all let-bindings, case-analyses, and applications. Also, all computations on a particular term end up being performed in one place.

Since the type parameters of "bind" are rigid, the uses of the right-hand side of "bind" are indexed by their return values. The terms end up in positions in the returned structure that make "bind" associate, therefore the uses of the right-hand side must be associative in the "monadified" "bind," and the resulting structure is a monad.

This is really wooly, so here is an example. Consider the following strict list monad:

``````rseq x y = case x of
x:xs -> (x:xs) : y
[] -> [] : y

evalList (x:xs) = rseq x (evalList xs)
evalList [] = []

instance Monad [] where
return x = [x]
ls >>= f = concat (evalList (map f ls))
``````

This order of evaluation leads to the standard ListT (not really a monad). However, by cut elimination:

``````instance Monad [] where
return x = [x]
ls >>= f = case ls of
[] -> []
x:xs -> case f x of
y:ys -> (y:ys) ++ (xs >>= f)
[] -> [] ++ (xs >>= f)
``````

This provides the exact evaluation order to be "monadified."

In response to Petr Pudlak:

If the type of the monad in question is some function type (it is convenient to Church-encode all data types), then the function type is converted by decorating all return values of the type with the transformed monad. This is the type portion of monadification. The value portion of monadification lifts pure functions using "return," and combines them with uses of inhabitants of the monad type using "bind," preserving the evaluation order of the original program text.

The strict list monad was given as an example of an evaluation order that does not compose associatively, as witnessed by the fact that ListT uses the same evaluation order as the strict list monad.

To complete the example, the Church encoding of the list monad is:

``````data List a = List (forall b. b -> (a -> List a -> b) -> b)
``````

``````data ListT m a = ListT (forall b. m b -> (a -> List a -> m b) -> m b)

cons x xs = \_ f -> f x xs

nil = \x _ -> x

instance (Monad m) => Monad (ListT m) where
return x = cons x nil
ls >>= f = ls nil (\x xs -> f x >>= \g ->
g (liftM (nil ++) (xs >>= f)) (\y ys -> liftM (cons y ys ++) (xs >>= f))
``````

To elaborate on the above, the cut elimination step forces all values to be consumed using a stack discipline, ensuring that the order of results in the structure matches the evaluation order -- this comes at the price of potentially running the same action many times.

[Technically, what you need is a cut elimination of approximants: A is a cut elimination (of approximants) of B, iff for every finite approximant of B, there is a finite approximant of A such that A is a cut elimination of B.]

I hope that helps.

• What is the exact definition of "monadified"? What is the purpose of having a strict list monad? Can you give an example, like how having the instance `Monad []` leads to the corresponding definition and instance of the corresponding monad transformer? How does cut elimination help to get there? – Petr Pudlák Aug 3 '15 at 18:47
• @PetrPudlák, @user2817408 If "monadification" is understood as "converting the source code of `p :: a` into `p' :: m a`" then I have a sort of a counterexample where this cannot be done. I am quoting from stackoverflow.com/questions/39649497/…: Suppose we have a program `p :: a` that internally uses a function `f :: b -> c`. Now, suppose we want to replace `f` by `f' :: b -> m c` for some monad `m`, so that the program `p` will become monadic as well: `p' :: m a`. Our task is to refactor `p` into `p'`. This can't work for arbitrary `m`. – winitzki May 11 '18 at 16:06
• @user2817408 Is there an algorithm that would find a monad transformer from an arbitrary given type constructor and a given implementation of a monad instance via pure functions? Let's limit ourselves to type constructors made out of any combinations of `->`, tuple, and `Either`. E.g. given the code `type F a = r -> Either (a, a) (a, a, Maybe a)` and an implementation of a monad instance for `F`, to find the code for the monad transformer `FT`. – winitzki May 11 '18 at 16:14
• I have one more thing to add. While the restriction to rigidity explained by winitzki does prevent the monad transformer from being constructed in general, there's a trick using Kan extensions that allows you to get monad transformers for other monads, at the price of accepting a Codensity-type structure along with it. Code is here pastebin.com/3A3Yd252 – James Candy Jun 3 '18 at 20:10
• @JamesCandy Your pastebin code is interesting, but I am a bit confused because I am not familiar with stuff like `O` and `unO`. Is your construction, `Lift g`, a general monad transformer for any `Monad g` that satisfies the laws? – winitzki Aug 9 '18 at 23:25