Co-Applicative programming style

coapplicative

This post showcases an upcoming addition to the contravariant package that permits programming in a “co-Applicative” (Divisible) style that greatly resembles Applicative style.

This post assumes that you are already familiar with programming in an Applicative style, but if you don’t know what that is then I recommend reading:

• Applicative Programming with Effects

Example

The easiest way to motivate this is through a concrete example:

{-# LANGUAGE NamedFieldPuns #-}

import Data.Functor.Contravariant (Predicate(..), (>$<))
import Data.Functor.Contravariant.Divisible (Divisible, divided)

nonNegative :: Predicate Double
nonNegative = Predicate (0 <=)

data Point = Point { x :: Double, y :: Double, z :: Double }

nonNegativeOctant :: Predicate Point
nonNegativeOctant = adapt >$< nonNegative >*< nonNegative >*< nonNegative
  where
    adapt Point{ x, y, z } = (x, (y, z))

-- | This operator will be available in the next `contravariant` release
(>*<) :: Divisible f => f a -> f b -> f (a, b)
(>*<) = divided

infixr 5 >*<

This code takes a nonNegative Predicate on Doubles that returns True if the double is non-negative and then uses co-Applicative (Divisible) style to create a nonNegativeOctant Predicate on Points that returns True if all three coordinates of a Point are non-negative.

The key part to zoom in on is the nonNegativeOctant Predicate, whose implementation superficially resembles the Applicative style that we know and love:

nonNegativeOctant = adapt >$< nonNegative >*< nonNegative >*< nonNegative

The difference is that instead of the <$> and <*> operators we use >$< and >*<, which are their evil twins dual operators¹. For example, you can probably see the resemblance to the following code that uses Applicative style:

readDouble :: IO Double
readDouble = readLn

readPoint :: IO Point
readPoint = Point <$> readDouble <*> readDouble <*> readDouble

Types

I’ll walk through the types involved to help explain how this style works.

First, we will take this expression:

nonNegativeOctant = adapt >$< nonNegative >*< nonNegative >*< nonNegative

… and explicitly parenthesize the expression instead of relying on operator precedence and associativity:

nonNegativeOctant = adapt >$< (nonNegative >*< (nonNegative >*< nonNegative))

So the smallest sub-expression is this one:

nonNegative >*< nonNegative

… and given that the type of nonNegative is:

nonNegative :: Predicate Double

… and the type of the (>*<) operator is:

(>*<) :: Divisible f => f a -> f b -> f (a, b)

… then we can specialize the f in that type to Predicate (since Predicate implements the Divisible class):

(>*<) :: Predicate a -> Predicate b -> Predicate (a, b)

… and further specialize a and b to Double:

(>*<) :: Predicate Double -> Predicate Double -> Predicate (Double, Double)

… and from that we can conclude that the type of our subexpression is:

nonNegative >*< nonNegative
    :: Predicate (Double, Double)

In other words, nonNegative >*< nonNegative is a Predicate whose input is a pair of Doubles.

We can then repeat the process to infer the type of this larger subexpression:

nonNegative >*< (nonNegative >*< nonNegative))
    :: Predicate (Double, (Double, Double))

In other words, now the input is a nested tuple of three Doubles.

However, we want to work with Points rather than nested tuples, so we pre-process the input using >$<:

adapt >$< (nonNegative >*< (nonNegative >*< nonNegative))
  where
    adapt :: Point -> (Double, (Double, Double))
    adapt Point{ x, y, z } = (x, (y, z))

… and this works because the type of >$< is:

(>$<) :: Contravariant f => (a -> b) -> f b -> f a

… and if we specialize f to Predicate, we get:

(>$<) :: (a -> b) -> Predicate b -> Predicate a

… and we can further specialize a and b to:

(>$<)
    :: (Point -> (Double, (Double, Double)))
    -> Predicate (Double, (Double, Double))
    -> Predicate Point

… which implies that our final type is:

nonNegativeOctant :: Predicate Point
nonNegativeOctant = adapt >$< (nonNegative >*< (nonNegative >*< nonNegative))
  where
    adapt Point{ x, y, z } = (x, (y, z))

Duals

We can better understand the relationship between the two sets of operators by studying their types:

-- | These two operators are dual to one another:
(<$>) :: Functor       f => (a -> b) -> f a -> f b
(>$<) :: Contravariant f => (a -> b) -> f b -> f a

-- | These two operators are similar in spirit, but they are not really dual:
(<*>) :: Applicative f => f (a -> b) -> f a -> f b
(>*<) :: Divisible   f => f a        -> f b -> f (a, b)

Okay, so (>*<) is not exactly the dual operator of (<*>). (>*<) is actually dual to liftA2 (,)²:

(>*<)      :: Divisible   f => f a -> f b -> f (a, b)
liftA2 (,) :: Applicative f => f a -> f b -> f (a, b)

In fact, if we were to hypothetically redefine (<*>) to be liftA2 (,) then we could write Applicative code that is even more symmetric to the Divisible code (albeit less ergonomic):

import Control.Applicative (liftA2)
import Prelude hiding ((<*>))

(<*>) = liftA2 (,)

infixr 5 <*>

readDouble :: IO Double
readDouble = readLn

readPoint :: IO Point
readPoint = adapt <$> readDouble <*> readDouble <*> readDouble
  where
    adapt (x, (y, z)) = Point{ x, y, z }

-- Compare to:
nonNegativeOctant :: Predicate Point
nonNegativeOctant = adapt >$< nonNegative >*< nonNegative >*< nonNegative
  where
    adapt Point{ x, y, z } = (x, (y, z))

It would be nice if we could create a (>*<) operator that was dual to the real (<*>) operator, but I could not figure out a good way to do this.

If you didn’t follow all of that, the main thing you should take away from this going into the next section is:

• the Contravariant class is the dual of the Functor class
• the Divisible class is the dual of the Applicative class

Syntactic sugar

GHC supports the ApplicativeDo extension, which lets you use do notation as syntactic sugar for Applicative operators. For example, we could have written our readPoint function like this:

{-# LANGUAGE ApplicativeDo #-}

readPoint :: IO Point
readPoint = do
    x <- readDouble
    y <- readDouble
    z <- readDouble
    return Point{ x, y, z }

… which behaves in the exact same way. Actually, we didn’t even need the ApplicativeDo extension because IO has a Monad instance and anything that has a Monad instance supports do notation without any extensions.

However, the ApplicativeDo language extension does change how the do notation is desugared. Without the extension the above readPoint function would desugar to:

readPoint =
    readDouble >>= \x ->
    readDouble >>= \y ->
    readDouble >>= \z ->
    return Point{ x, y, z }

… but with the ApplicativeDo extension the function instead desugars to only use Applicative operations instead of Monad operations:

-- I don't know the exact desugaring logic, but I imagine it's similar to this:
readPoint = adapt <$> readDouble <*> readDouble <*> readDouble
  where
    adapt x y z = Point{ x, y, z }

So could there be such a thing as “DivisibleDo” which would introduce syntactic sugar for Divisible operations?

I think there could be such an extension, and there are several ways you could design the user experience.

One approach would be to permit code like this:

{-# LANGUAGE DivisibleFrom #-}

nonNegativeOctant :: Predicate Point
nonNegativeOctant =
    from Point{ x, y, z }
        x -> nonNegative
        y -> nonNegative
        z -> nonNegative

… which would desugar to the original code that we wrote:

nonNegativeOctant = adapt >$< nonNegative >*< nonNegative >*< nonNegative
  where
    adapt Point{ x, y, z } = (x, (y, z))

Another approach could be to make the syntax look exactly like do notation, except that information flows in reverse:

{-# LANGUAGE DivisibleDo #-}

nonNegativeOctant :: Predicate Point
nonNegativeOctant = do
    x <- nonNegative
    y <- nonNegative
    r <- nonNegative
    return Point{ x, y, z } -- `return` here would actually be a special keyword

I assume that most people will prefer the from notation, so I’ll stick to that for now.

If we were to implement the former DivisibleFrom notation then the Divisible laws stated using from notation would become:

-- Left identity
  from x
      x -> m
      x -> conquer

= m


-- Right identity
  from x
      x -> conquer
      x -> m

= m

-- Associativity
  from (x, y, z)
      (x, y) -> from (x, y)
                    x -> m
                    y -> n
      z -> o

= from (x, y, z)
      x -> m
      (y, z) -> from (y, z)
                    y -> n
                    z -> o

= from (x, y, z)
      x -> m
      y -> n
      z -> o

This explanation of how DivisibleFrom would work is really hand-wavy, but if people were genuinely interested in such a language feature I might take a stab at making the semantics of DivisibleFrom sufficiently precise.

History

The original motivation for the (>*<) operator and Divisible style was to support compositional RecordEncoders for the dhall package.

Dhall’s Haskell API defines a RecordEncoder type which specifies how to convert a Haskell record to a Dhall syntax tree, and we wanted to be able to use the Divisible operators to combine simpler RecordEncoders into larger RecordEncoders, like this:

data Project = Project
    { name        :: Text
    , description :: Text
    , stars       :: Natural
    }

injectProject :: Encoder Project
injectProject =
  recordEncoder
    ( adapt >$< encodeFieldWith "name"        inject
            >*< encodeFieldWith "description" inject
            >*< encodeFieldWith "stars"       inject
    )
  where
    adapt Project{..} = (name, (description, stars))

The above example illustrates how one can assemble three smaller RecordEncoders (each of the encodeFieldWith functions) into a RecordEncoder for the Project record by using the Divisible operators.

If we had a DivisibleFrom notation, then we could have instead written:

injectProject =
    recordEncoder from Project{..}
        name        -> encodeFieldWith "name"        inject
        description -> encodeFieldWith "description" inject
        stars       -> encodeFieldWith "stars"       inject

If you’d like to view the original discussion that led to this idea you can check out the original pull request.

Conclusion

I upstreamed this (>*<) operator into the contravariant package, which means that you’ll be able to use the trick outlined in this post after the next contravariant release.

Until then, you can define your own (>*<) operator inline within your own project, which is what dhall did while waiting for the operator to be upstreamed.

---

1. Alright, they’re not categorically dual in a rigorous sense, but I couldn’t come up with a better term to describe their relationship to the original operators.↩︎

2. I feel like liftA2 (,) should have already been added to Control.Applicative by now since I believe it’s a pretty fundamental operation from a theoretical standpoint.↩︎

by Gabriella Gonzalez (noreply@blogger.com) at October 21, 2021 03:26 PM

Proving Commutativity of Polysemy Interpreters

To conclude this series of posts on polysemy-check, today we’re going to talk about how to ensure your effects are sane. That is, we want to prove that correct interpreters compose into correct programs. If you’ve followed along with the series, you won’t be surprised to note that polysemy-check can test this right out of the box.

But first, what does it mean to talk about the correctness of composed interpreters? This idea comes from Yang and Wu’s Reasoning about effect interaction by fusion. The idea is that for a given program, changing the order of two subsequent actions from different effects should not change the program. Too abstract? Well, suppose I have two effects:

foo :: Member Foo r => Sem r ()
bar :: Member Bar r => Sem r ()

Then, the composition of interpreters for Foo and Bar is correct if and only if¹ the following two programs are equivalent:

forall m1 m2.
  m1 >> foo >> bar >> m2
=
  m1 >> bar >> foo >> m2

That is, since foo and bar are actions from different effects, they should have no influence on one another. This sounds like an obvious property; effects correspond to individual units of functionality, and so they should be completely independent of one another. At least — that’s how we humans think about things. Nothing actually forces this to be the case, and extremely hard-to-find bugs will occur if this property doesn’t hold, because it breaks a mental abstraction barrier.

It’s hard to come up with good examples of this property being broken in the wild, so instead we can simulate it with a different broken abstraction. Let’s imagine we’re porting a legacy codebase to polysemy, and the old code hauled around a giant stateful god object:

data TheWorld = TheWorld
  { counter :: Int
  , lots    :: Int
  , more'   :: Bool
  , stuff   :: [String]
  }

To quickly get everything ported, we replaced the original StateT TheWorld IO application monad with a Member (State TheWorld) r constraint. But we know better than to do that for the long haul, and instead are starting to carve out effects. We introduce Counter:

data Counter m a where
  Increment :: Counter m ()
  GetCount :: Counter m Int

makeSem ''Counter

with an interpretation into our god object:

runCounterBuggy
    :: Member (State TheWorld) r
    => Sem (Counter ': r) a
    -> Sem r a
runCounterBuggy = interpret $ \case
  Increment ->
    modify $ \world -> world
                         { counter = counter world + 1
                         }
  GetCount ->
    gets counter

On its own, this interpretation is fine. The problem occurs when we use runCounterBuggy to handle Counter effects that coexist in application code that uses the State TheWorld effect. Indeed, polysemy-check tells us what goes wrong:

quickCheck $
  prepropCommutative @'[State TheWorld] @'[Counter] $
    pure . runState defaultTheWorld . runCounterBuggy

we see:

Failed.

Effects are not commutative!

k1  = Get
e1 = Put (TheWorld 0 0 False [])
e2 = Increment
k2  = Pure ()

(k1 >> e1 >> e2 >> k2) /= (k1 >> e2 >> e1 >> k2)
(TheWorld 1 0 False [],()) /= (TheWorld 0 0 False [],())

Of course, these effects are not commutative under the given interpreter, because changing State TheWorld will overwrite the Counter state! That’s not to say that this sequence of actions actually exists anywhere in your codebase, but it’s a trap waiting to happen. Better to take defensive action and make sure nobody can ever even accidentally trip this bug!

The bug is fixed by using a different data store for Counter than TheWorld. Maybe like this:

runCounter
    :: Sem (Counter ': r) a
    -> Sem r a
runCounter = (evalState 0) . reinterpret @_ @(State Int) $ \case
  Increment -> modify (+ 1)
  GetCount -> get

Contrary to the old handler, runCounter now introduces its own anonymous State Int effect (via reinterpret), and then immediately eliminates it. This ensures the state is invisible to all other effects, with absolutely no opportunity to modify it. In general, this evalState . reintrpret pattern is a very good one for implementing pure effects.

Of course, a really complete solution here would also remove the counter field from TheWorld.

Behind the scenes, prepropCommutative is doing exactly what you’d expect — synthesizing monadic preludes and postludes, and then randomly pulling effects from each set of rows and ensuring everything commutes.

At first blush, using prepropCommutative to test all of your effects feels like an \(O(n^2)\) sort of deal. But take heart, it really isn’t! Let’s say our application code requires Members (e1 : e2 : e3 : es) r, and our eventual composed interpreter is runEverything :: Sem ([e] ++ es ++ [e3, e2, e1] ++ impl) a -> IO (f a). Here, we only need \(O(es)\) calls to prepropCommutative:

• prepropCommutative @'[e2] @'[e1] runEverything
• prepropCommutative @'[e3] @'[e2, e1] runEverything
• …
• prepropCommutative @'[e] @'(es ++ [e2, e1]) runEverything

The trick here is that we can think of the composition of interpreters as an interpreter of composed effects. Once you’ve proven an effect commutes with a particular row, you can then add that effect into the row and prove a different effect commutes with the whole thing. Induction is pretty cool!

As of today there is no machinery in polysemy-check to automatically generate this linear number of checks, but it seems like a good thing to include in the library, and you can expect it in the next release.

To sum up these last few posts, polysemy-check is an extremely useful and versatile tool for proving correctness about your polysemy programs. It can be used to show the semantics of your effects (and adherence of such for their interpreters.) It can show the equivalence of interpreters — such as the ones you use for testing, and those you use in production. And now we’ve seen how to use it to ensure that the composition of our interpreters maintains its correctness.

Happy testing!

---

1. Well, there is a second condition regarding distributivity that is required for correctness. The paper goes into it, but polysemy-check doesn’t yet implement it.↩︎

October 21, 2021 12:53 AM

Type-checking plugins, Part I: Why write a type-checking plugin?

Type-checking plugins for GHC are a powerful tool which allows users to inject domain-specific knowledge into GHC’s type-checker. In this series of posts, we will explore why you might want to write your own plugin, and how to do so.

• I: Why write a type-checking plugin?
• II: GHC’s constraint solver
• III: Writing a type-checking plugin

In this first blog post of the series, I’ll be outlining a few examples that showcase some limitations in GHC’s instance resolution and type family reduction mechanisms. With a type-checker plugin, we are no longer restricted by these limitations, and can decide ourselves how to solve constraints and reduce type families.

Instance resolution

Recall how GHC goes about instance resolution, as per the user’s guide. A typeclass instance has two components:

instance ctxt => Cls arg_1 ... arg_n

To the left of => is the instance context, and to the right the instance head. To solve a constraint like Cls x_1 ... x_n, GHC goes through all the class instance declarations for Cls, trying to match the arguments x_1, ..., x_n against the arguments arg_1, ..., arg_n appearing in the instance head. Once it finds such an instance (which should be unique, unless one is using overlapping instances), GHC commits to it, picking up the context as a Wanted constraint (we will cover Wanted and Given constraints in depth in Part II: § Constraint solving).

However, one might be interested in using a different method to resolve instances. Let’s look at two simple examples.

State machines

Suppose we want to implement a state machine: each state corresponds to a type, and we can transition values between types according to certain rules. This can be implemented as a typeclass: arrows in the state diagram are typeclass instances.

type Transition :: Type -> Type -> Constraint
class Transition a b where { transition :: a -> b }

We could start by defining some basic instances:

instance Transition A B where {..}
instance Transition B C where {..}
instance Transition C D where {..}
instance Transition A E where {..}
instance Transition B F where {..}
instance Transition E F where {..}

Then, we might want the compiler to use composition to solve other instances. For example, when trying to solve Transition A D, we notice that there is a unique path

A -> B -> C -> D

which would allow us to compose the transition functions to obtain a transition function of type A -> D. On the other hand, if we want a transition from A to F, we notice that there are two different paths, namely A -> B -> F, and A -> E -> F. We could either reject this, or perhaps choose one of the two paths arbitrarily.

This goes beyond GHC’s instance resolution mechanisms, but we could implement a graph reachability test in a type-checking plugin to solve general Transition X Y instances.

Constraint disjunction

The central feature of typeclasses is that they are open: one can define a typeclass and keep adding instances to it. This is in contrast to something like a datatype

data ABC
  = A
  | B Int
  | C Float Bool

which is closed: users can’t add new constructors to ABC in their own modules.

This property of typeclasses comes with a fundamental limitation: we can’t know in advance whether a typeclass constraint is satisfied. A typeclass constraint that was insoluble at some point might become solvable in another context (e.g. a user could define a Show (Bool -> Int) instance).

As a result, GHC does not offer any mechanism for determining whether a constraint is satisfied, as this could result in incoherent behaviour.¹ This is unfortunate, as this can be quite useful: for example, one might want to implement an arithmetic computation differently for integral vs floating-point numbers, to ensure numerical stability:

stableAlgorithm = select @(Floating a) @(Num a) fp_algo int_algo
  where
    fp_algo  :: Floating a => [a] -> a -- floating-point algorithm
    int_algo ::      Num a => [a] -> a -- integral algorithm

Here, the select function dispatches on whether the first constraint (in this case Floating a) is satisfied; when it is, it uses the first (visible) argument; otherwise, the second. This behaviour can be implemented in a type-checker plugin (see for instance my if-instance plugin): when attempting to solve a constraint disjunction ct1 || ct2, we can simply look up whether ct1 is currently satisfiable, disregarding the fact that new instances might be defined later (which can lead to incoherence as mentioned above). The satisfiability of ct1 at the point of solving the disjunction ct1 || ct2 will then determine which implementation is selected.

Stuck type families

Consider the type family

type (+) :: Nat -> Nat -> Nat
type family a + b where
  Zero   + b = b
  Succ a + b = Succ (a + b)

GHC can only reduce a + b when it knows what a is: is it Zero or is it Succ i for some i? This causes a problem when we don’t have concrete natural numbers, but still want to reason about (+):

infixr 5 :<
type Vec :: Nat -> Type -> Type
data Vec n a where
  Nil  :: Vec Zero a
  (:<) :: a -> Vec n a -> Vec (Succ n) a

-- | Interweave the elements of two vectors.
weave :: Vec n a -> Vec n a -> Vec (n + n) a
weave Nil       Nil       = Nil
weave (a :< as) (b :< bs) = a :< b :< weave as bs

To typecheck weave, we need to know that

Succ n + Succ n ~ Succ (Succ (n + n))

Using the second type family equation on the LHS, this reduces to:

Succ (n + Succ n) ~ Succ (Succ (n + n))

Peeling off Succ:

n + Succ n ~ Succ (n + n)

Now we can’t make any more progress: we don’t know which equation of (+) to use, as the first argument is a bare type variable n. We say the type family application is stuck; it doesn’t reduce.

By contrast, in a type-checking plugin, we can rewrite type-family applications involving variables, and thus implement a solver for natural number arithmetic.

Type family arguments

Suppose we are interested in solving a theory of row types, e.g. to implement a framework of extensible records.

A row is an unordered association map, field name ⇝ type, e.g.

myRow = ( "intField" :: Int, "boolField" :: Bool, "anotherInt" :: Int )

Crucially, order doesn’t matter in a row. To communicate this fact to the type-checker, we would want to be able to prove a fact such as:

Insert k v (Insert l w r) ~ Insert l w (Insert k v r)

when k and l are distinct field names that don’t appear in the row r. However, we can’t write a type family equation of the sort:

type Insert :: Symbol -> Type -> Row -> Row
type family Insert k v r where
  Insert k v (Insert l w r) = ...

• Illegal type synonym family application ‘Insert l w row’ in instance:
    Insert k v (Insert l w row)

GHC doesn’t allow type families to appear inside the LHS of type family equations. Doing so would risk non-confluence: the result of type-family reduction might depend on the order in which we rewrite arguments. For example:

type F :: Type -> Type
type family F a where
  F (F a) = a       -- F[0]
  F Bool  = Float   -- F[1]
  F a     = Maybe a -- F[2]

Given a type such as F (F Bool), we can proceed in two ways:

1. Reduce the outer type family application first, using the first equation (written F[0]). This yields the reduction F (F Bool) ~~> Bool.
2. Reduce the argument first, using the second equation, F[1], and following up with F[2]: F (F Bool) ~~> F Float ~~> Maybe Float.

We obtained different results depending on the order in which reductions were performed. To avoid this problem, GHC simply disallows type family applications from appearing on the LHS of type family equations.

In a type-checking plugin, we can inspect the arguments of a type family, and use that information in deciding how to reduce the type family application.

Performance of type-family reduction

The current implementation of type families in GHC suffers from one significant problem: they can be painfully slow.

This is because, when GHC reduces a type family application, it also creates a proof that keeps track of which type family equations were used. Such proofs can be large, in particular when using recursive type families. Returning to the example of natural number addition:

type (+) :: Nat -> Nat -> Nat
type family a + b where
  Zero   + b = b
  Succ a + b = Succ (a + b)

The proof that 5 + 0 reduces to 5, in the coercion language that will be explained in Part II: § Constraint solving, is as follows:

+[1] <Succ (Succ (Succ (Succ Zero)))> <Zero>
; (Succ (+[1] <Succ (Succ (Succ Zero))> <Zero>
        ; (Succ (+[1] <Succ (Succ Zero)> <Zero>
                ; (Succ (+[1] <Succ Zero> <Zero>
                        ; (Succ (+[1] <Zero> <Zero>
                                ; (Succ (+[0] <Zero>))))))))))

Here +[0] refers to the first type-family equation of +, and +[1] to the second. The difficulty is that, in this proof language, we store the types of the arguments. For example, in the first reduction step, in which we reduce Succ (Succ (Succ (Succ (Succ Zero)))) + Zero to Succ (Succ (Succ (Succ (Succ Zero))) + 0), the proof records the two arguments to +, namely Succ (Succ (Succ (Succ Zero))) and Zero. As a result, the size of the proof that n + 0 reduces to n is quadratic in n.

This can be a problem, for example, in libraries that implement large sum or product types using type families and type-level lists (like many anonymous record libraries do), causing slow compile-times for even moderately-sized records.

In a type-checking plugin, we can instead perform type-family reduction in a single step, returning a single proof term which omits the intermediate steps. In this way, type-checking plugins allow us to sidestep many of the performance issues that surround type families.

Practical examples

• Solving with arithmetic expressions of natural numbers with Christiaan Baaij’s ghc-typelits-natnormalise,
• units of measure and dimensional analysis with Adam Gundry’s uom-plugin,
• regular expressions with Oleg Grenrus’s kleene-type,
• row types with Divesh Otwani and Richard Eisenberg’s thoralf,
• intrinsically typed System F with a solver for a lambda calculus of explicit substitutions, bundled with the ghc-tcplugin-api library.

Conclusion

We’ve seen that type-checking plugins can be useful in many different circumstances:

• custom constraint-solving logic,
• added flexibility for type-family reduction,
• performance considerations.

The next question is then, hopefully: how does one actually write a type-checking plugin? Because type-checking plugins operate directly on constraints, it’s important to be somewhat familiar with GHC’s constraint solver, and how type-checking plugins interact with it.

This will be the topic of Part II of this series, before we dive into the practical aspects of actually writing and debugging a type-checking plugin in Part III.

---

1. In this context, coherence is the property that the runtime behaviour of programs does not depend on the specific way in which they are typechecked.

   ↩

October 21, 2021 12:00 AM

Induction without core-size blow-upa.k.a. Large records: anonymous edition

An important factor affecting compilation speed and memory requirements is the size of the core code generated by ghc from Haskell source modules. Thus, if compilation time is an issue, this is something we should be conscious of and optimize for. In part 1 of this blog post we took an in-depth look at why certain Haskell constructs lead to quadratic blow-up in the generated ghc core code, and how the large-records library avoids these problems. Indeed, the large-records library provides support for records, including support for generic programming, with a guarantee that the generated core is never more than O(n) in the number of record fields.

The approach described there does however not directly apply to the case of anonymous records. This is the topic we will tackle in this part 2. Unfortunately, it seems that for anonymous records the best we can hope for is O(n log n), and even to achieve that we need to explore some dark corners of ghc. We have not attempted to write a new anynomous records library, but instead consider the problems in isolation; on the other hand, the solutions we propose should be applicable in other contexts as well. Apart from section Putting it all together, the rest of this blog post can be understood without having read part 1.

This work was done on behalf of Juspay; we will discuss the context in a bit more detail in the conclusions.

Recap: The problem of type arguments

Consider this definition of heterogenous lists, which might perhaps form the (oversimplified) basis for an anonymous records library:

data HList xs where
  Nil  :: HList '[]
  (:*) :: x -> HList xs -> HList (x ': xs)

If we plot the size of the core code generated by ghc for a Haskell module containing only a single HList value

newtype T (i :: Nat) = MkT Word

type ExampleFields = '[T 00, T 01, .., , T 99]

exampleValue :: HList ExampleFields
exampleValue = MkT 00 :* MkT 01 :* .. :* MkT 99 :* Nil

we get an unpleasant surprise:

The source of this quadratic behaviour is type annotations. The translation of exampleValue in ghc core is shown below (throughout this blog post I will show “pseudo-coreâ€�, using standard Haskell syntax):

exampleValue :: HList ExampleFields
exampleValue =
      (:*) @(T 00) @'[T 01, T 02, .., T 99] (MkT 00)
    $ (:*) @(T 01) @'[      T 02, .., T 99] (MkT 01)
      ..
    $ (:*) @(T 99) @'[                    ] (MkT 99)
    $ Nil

Every application of the (:*) constructor records the names and types of the remaining fields; clearly, this list is O(n) in the size of the record, and since there are also O(n) applications of (:*), this term is O(n²) in the number of elements in the HList.

We covered this in detail in part 1. In the remainder of this part 2 we will not be concerned with values of HList (exampleValue), but only with the type-level indices (ExampleFields).

Instance induction considered harmful

A perhaps surprising manifestation of the problem of quadratic type annotations arises for certain type class dictionaries. Consider this empty class, indexed by a type-level list, along with the customary two instances, for the empty list and an inductive instance for non-empty lists:

class EmptyClass (xs :: [Type])

instance EmptyClass '[]
instance EmptyClass xs => EmptyClass (x ': xs)

requireEmptyClass :: EmptyClass xs => Proxy xs -> ()
requireEmptyClass _ = ()

Let’s plot the size of a module containing only a single usage of this function:

requiresInstance :: ()
requiresInstance = requireEmptyClass (Proxy @ExampleFields)

Again, we plot the size of the module against the number of record fields (number of entries in ExampleFields):

The size of this module is practically identical to the size of the module containing exampleValue, because at the core level they actually look very similar. The translation of requiresEmptyClass looks something like like this:

d00  :: EmptyClass '[T 00, T 01, .., T 99]
d01  :: EmptyClass '[      T 01, .., T 99]
..
d99  :: EmptyClass '[                T 99]
dNil :: EmptyClass '[                    ]

d00  = fCons @'[T 01, T 02, .., T 09] @(T 00) d01
d01  = fCons @'[      T 02, .., T 99] @(T 01) d02
..
d99  = fCons @'[                    ] @(T 99) dNil
dNil = fNil

requiresInstance :: ()
requiresInstance = requireEmptyClass @ExampleFields d00 (Proxy @ExampleFields)

The two EmptyClass instances we defined above turn into two functions fCons and fNil, with types

fNil  :: EmptyClass '[]
fCons :: EmptyClass xs -> EmptyClass (x ': xs)

which are used to construct dictionaries. These look very similar to the Nil and (:*) constructor of HList, and indeed the problem is the same: we have O(n) calls to fCons, and each of those records all the remaining fields, which is itself O(n) in the number of record fields. Hence, we again have core that is O(n²).

Note that this is true even though the class is empty! It therefore really does not matter what we put inside the class: any induction of this shape will immediately result in quadratic blow-up. This was already implicit in part 1 of this blog post, but it wasn’t as explicit as it perhaps should have been—at least, I personally did not have it as clearly in focus as I do now.

It is true that if both the module defining the instances and the module using the instance are compiled with optimisation enabled, that might all be optimised away eventually, but it’s not that easy to know precisely when we can depend on this. Moreover, if our goal is to improve compilation time (and therefore the development cycle), we anyway typically do not compile with optimizations enabled.

Towards a solution

For a specific concrete record we can avoid the problem by simply not using induction. Indeed, if we add

instance {-# OVERLAPPING #-} EmptyClass ExampleFields

to our module, the size of the compiled module drops from 25,462 AST nodes to a mere 15 (that’s 15 full stop, not 15k!). The large-records library takes advantage of this: rather than using induction to define instances, it generates a single instance for each record type, which has constraints for every field in the record. The result is code that is O(n) in the size of the record.

The only reason large-records can do this, however, is that every record is explicitly declared. When we are dealing with anonymous records such an explicit declaration does not exist, and we have to use induction of some form. An obvious idea suggests itself: why don’t we try halving the list at every step, rather than reducing it by one, thereby reducing the code from O(n²) to O(n log n)?

Let’s try. To make the halving explicit¹, we define a binary Tree type², which we will use promoted to the type-level:

data Tree a =
    Zero
  | One a
  | Two a a
  | Branch a (Tree a) (Tree a)

EmptyClass is now defined over trees instead of lists:

class EmptyClass (xs :: Tree Type) where

instance EmptyClass 'Zero
instance EmptyClass ('One x)
instance EmptyClass ('Two x1 x2)
instance (EmptyClass l, EmptyClass r) => EmptyClass ('Branch x l r)

We could also change HList to be parameterized over a tree instead of a list of fields. Ideally this tree representation should be an internal implementation detail, however, and so we instead define a translation from lists to balanced trees:

-- Evens [0, 1, .. 9] == [0, 2, 4, 6, 8]
type family Evens (xs :: [Type]) :: [Type] where
  Evens '[]            = '[]
  Evens '[x]           = '[x]
  Evens (x ': _ ': xs) = x ': Evens xs

-- Odds [0, 1, .. 9] == [1, 3, 5, 7, 9]
type family Odds (xs :: [Type]) :: [Type] where
  Odds '[]       = '[]
  Odds (_ ': xs) = Evens xs

type family ToTree (xs :: [Type]) :: Tree Type where
  ToTree '[]       = 'Zero
  ToTree '[x]      = 'One x
  ToTree '[x1, x2] = 'Two x1 x2
  ToTree (x ': xs) = 'Branch x (ToTree (Evens xs)) (ToTree (Odds xs))

and then redefine requireEmptyClass to do the translation:

requireEmptyClass :: EmptyClass (ToTree xs) => Proxy xs -> ()
requireEmptyClass _ = ()

The use sites (requiresInstance) do not change at all. Let’s measure again:

Total failure. Not only did we not improve the situation, it got significantly worse.

What went wrong?

To understand, let’s look at the case for when we have 10 record fields. The generated code looks about as clean as one might hope for:

dEx :: EmptyClass (ToTree ExampleFields)
dEx = dTree `cast` <..>

dTree :: EmptyClass (
             'Branch
               (T 0)
               ('Branch (T 1) ('Two (T 3) (T 7)) ('Two (T 5) (T 9)))
               ('Branch (T 2) ('Two (T 4) (T 8)) ('One (T 6)))
           )
dTree =
    fBranch
      @('Branch (T 1) ('Two (T 3) (T 7)) ('Two (T 5) (T 9)))
      @('Branch (T 2) ('Two (T 4) (T 8)) ('One (T 6)))
      @(T 0)
      ( fBranch
           @('Two (T 3) (T 7))
           @('Two (T 5) (T 9))
           @(T 1)
           (fTwo @(T 3) @(T 7))
           (fTwo @(T 5) @(T 9))
      )
      ( -- .. right branch similar
      )

requiresInstance :: ()
requiresInstance = requireEmptyClass @ExampleFields dEx (Proxy @ExampleFields)

Each recursive call to the dictionary construction function fBranch is now indeed happening at half the elements, as intended.

The need for a cast

The problem is in the first line:

dEx = dTree `cast` <..>

Let’s first understand why we have a cast here at all:

1. The type of the function that we are calling is

   requireEmptyClass :: forall xs. EmptyClass (ToTree xs) => Proxy xs -> ()

   We must pick a value for xs: we pick ExampleFields.

2. In order to be able to call the function, we must produce evidence (that is, a dictionary) for EmptyClass (ToTree ExampleFields). We therefore have to evaluate ToTree ... to ('Branch ...); as we do that, we construct a proof Ï€ that ToTree ... is indeed equal to the result (Branch ...) that we computed.

3. We now have evidence of EmptyClass ('Branch ...), but we need evidence of EmptyClass (ToTree ...). This is where the cast comes in: we can coerce one to the other given a proof that they are equal; since Ï€ proves that

   ToTree ... ~ 'Branch ...

   we can construct a proof that

   EmptyClass (ToTree ...) ~ EmptyClass ('Branch ...)

   by appealing to congruence (if x ~ y then T x ~ T y).

The part in square brackets <..> that I elided above is precisely this proof.

Proofs

Let’s take a closer look at what that proof looks like. I’ll show a simplified form³, which I hope will be a bit easier to read and in which the problem is easier to spot:

  ToTree[3] (T 0) '[T 1, T 2, T 3, T 4, T 5, T 6, T 7, T 8, T 9]
; Branch (T 0)
    ( Evens[2] (T 1) (T 2) '[T 3, T 4, T 5, T 6, T 7, T 8, T 9]
    ; Evens[2] (T 3) (T 4) '[T 5, T 6, T 7, T 8, T 9]
    ; Evens[2] (T 5) (T 6) '[T 7, T 8, T 9]
    ; Evens[2] (T 7) (T 8) '[T 9]
    ; Evens[1] (T 9)
    ; ToTree[3] (T 1) '[T 3, T 5, T 7, T 9]
    ; Branch (T 1)
        ( Evens[2] (T 3) (T 5) '[T 7, T 9]
        ; Evens[2] (T 7) (T 9) '[]
        ; Evens[0]
        ; ToTree[2] (T 3) (T 7)
        )
        ( Odds[1] (T 3) '[T 5, T 7, T 9]
        ; Evens[2] (T 5) (T 7) '[T 9]
        ; Evens[1] (T 9)
        ; ToTree[2] (T 5) (T 9)
        )
    )
    ( Odds[1] (T 1) '[T 2, T 3, T 4, T 5, T 6, T 7, T 8, T 9]
    ; .. -- omitted (similar to the left branch)
    )

The “axiomsâ€� in this proof – ToTree[3], Evens[2], etc. – refer to specific cases of our type family definitions. Essentially the proof is giving us a detailed trace of the evaluation of the type families. For example, the proof starts with

ToTree[3] (T 0) '[T 1, T 2, T 3, T 4, T 5, T 6, T 7, T 8, T 9]

which refers to the fourth line of the ToTree definition

ToTree (x ': xs) = 'Branch x (ToTree (Evens xs)) (ToTree (Odds xs))

recording the fact that

  ToTree '[T 0, .., T 9]
~ 'Branch (T 0) (ToTree (Evens '[T 1, .. T9])) (ToTree (Odds '[T 1, .. T9]))

The proof then splits into two, giving a proof for the left subtree and a proof for the right subtree, and here’s where we see the start of the problem. The next fact that the proof establishes is that

Evens '[T 1, .. T 9] ~ '[T 1, T 3, T 5, T 7, T 9]

Unfortunately, the proof to establish this contains a line for every evaluation step:

  Evens[2] (T 1) (T 2) '[T 3, T 4, T 5, T 6, T 7, T 8, T 9]
; Evens[2] (T 3) (T 4) '[T 5, T 6, T 7, T 8, T 9]
; Evens[2] (T 5) (T 6) '[T 7, T 8, T 9]
; Evens[2] (T 7) (T 8) '[T 9]
; Evens[1] (T 9)

We have O(n) such steps, and each step itself has O(n) size since it records the remaining list. The coercion therefore has size O(n²) at every branch in the tree, leading to an overall coercion also⁴ of size O(n²).

Six or half a dozen

So far we defined

requireEmptyClass :: EmptyClass (ToTree xs) => Proxy xs -> ()
requireEmptyClass _ = ()

and are measuring the size of the core generated for a module containing

requiresInstance :: ()
requiresInstance = requireEmptyClass (Proxy @ExampleFields)

for some list ExampleFields. Suppose we do one tiny refactoring, and make the caller use ToList instead; that is, requireEmptyClass becomes

requireEmptyClass :: EmptyClass t => Proxy t -> ()
requireEmptyClass _ = ()

and we now call ToTree at the use site instead:

requiresInstance :: ()
requiresInstance = requireEmptyClass (Proxy @(ToTree ExampleFields))

Let’s measure again:

The quadratic blow-up disappeared! What happened? Just to add to the confusion, let’s consider one other small refactoring, leaving the definition of requireEmptyClass the same but changing the use site to

requiresInstance = requireEmptyClass @(ToTree ExampleFields) Proxy

Measuring one more time:

Back to blow-up! What’s going on?

Roles

We will see in the next section that the difference is due to roles. Before we look at the details, however, let’s first remind ourselves what roles are⁵. When we define

newtype Age = MkAge Int

then Age and Int are representationally equal but not nominally equal: if we have a function that wants an Int but we pass it an Age, the type checker will complain. Representational equality is mostly a run-time concern (when do two values have the same representation on the runtime heap?), whereas nominal equality is mostly a compile-time concern. Nominal equality implies representional equality, of course, but not vice versa.

Nominal equality is a very strict equality. In the absence of type families, types are only nominally equal to themselves; only type families introduce additional axioms. For example, if we define

type family F (a :: Type) :: Type where
  F Int = Bool
  F Age = Char

then F Int and Bool are considered to be nominally equal.

When we check whether two types T a and T b are nominally equal, we must simply check that a and b are nominally equal. To check whether T a and T b are representionally equal is however more subtle [Safe zero-cost coercions for Haskell, Fig 3]. There are three cases to consider, illustrated by the following examples:

data T1 x = T1
data T2 x = T2 x
data T3 x = T3 (F x)

Then

• T1 a and T1 b are representionally equal no matter the values of a and b: we say that x has a phantom role.
• T2 a and T2 b are representionally equal if a and b are: x has a representional role.
• T3 a and T3 b are representionally equal if a and b are nominally equal: x has a nominal role (T3 Int and T3 Age are certainly not representionally equal, even though Int and Age are!).

This propagates up; for example, in

data ShowType a = ShowType {
      showType :: Proxy a -> String
    }

the role of a is phantom, because a has a phantom role in Proxy. The roles of type arguments are automatically inferred, and usually the only interaction programmers have with roles is through

coerce :: Coercible a b => a -> b

where Coercible is a thin layer around representational equality. Roles thus remain invisible most of the time—but not today.

Proxy versus type argument

Back to the problem at hand. To understand what is going on, we have to be very precise. The function we are calling is

requireEmptyClass :: EmptyClass xs => Proxy xs -> ()
requireEmptyClass _ = ()

The question we must carefully consider is: what are we instantiating xs to? In the version with the quadratic blowup, where the use-site is

requiresInstance = requireEmptyClass @(ToTree ExampleFields) Proxy

we are being very explicit about the choice of xs: we are instantiating it to ToTree ExampleFields. In fact, we are more explicit than we might realize: we are instantiating it to the unevaluated type ToTree ExampleFields, not to ('Branch ...). Same thing, you might object, and you’d be right—but also wrong. Since we are instantiating it to the unevaluated type, but then build a dictionary for the evaluated type, we must then cast that dictionary; this is precisely the picture we painted in section What went wrong? above.

The more surprising case then is when the use-site is

requiresInstance = requireEmptyClass (Proxy @(ToTree ExampleFields))

In this case, we’re leaving ghc to figure out what to instantiate xs to. It will therefore instantiate it with some fresh variable �. When it then discovers that we also have a Proxy � argument, it must unify � with ToTree ExampleFields. Crucially, when it does so, it instantiates � to the evaluated form of ToTree ExampleFields (i.e., Branch ...), not the unevaluated form. In other words, we’re effectively calling

requiresInstance = requireEmptyClass @(Branch _ _ _) (Proxy @(ToTree ExampleFields))

Therefore, we need and build evidence for EmptyClass (Branch ...), and there is no need for a cast on the dictionary.

However, the need for a cast has not disappered: if we instantiate xs to (Branch ...), but provide a proxy for (ToTree ...), we need to cast the proxy instead—so why the reduction in core size? Let’s take a look at the equality proof given to the cast:

   Univ(phantom phantom <Tree *>
-- (1)    (2)      (3)     (4)
     :: ToTree ExampleFields         -- (5)
      , 'Branch  (T 0)               -- (6)
           ('Branch (T 1)
               ('Two (T 3) (T 7))
               ('Two (T 5) (T 9)))
           ('Branch (T 2)
               ('Two (T 4) (T 8))
               ('One (T 6)))
)

This is it! The entire coercion that was causing us trouble has been replaced basically by a single-constructor “trust meâ€� universal coercion. This is the only coercion that establishes “phantom equalityâ€�⁶. Let’s take a closer look at the coercion:

1. Univ indicates that this is a universal coercion.
2. The first occurrence of phantom is the role of the equality that we’re establishing.
3. The second occurrence of phantom is the provenance of the coercion: what justifies the use of a universal coercion? Here this is phantom again (we can use a universal coercion when establishing phantom equality), but this is not always the case; one example is unsafeCoerce, which can be used to construct a universal coercion between any two types at all⁷.
4. When we establish the equality of two types ğ�œ�1 :: ğ�œ…1 and ğ�œ�2 :: ğ�œ…2, we also need to establish that the two kinds ğ�œ…1 and ğ�œ…2 are equal. In our example, both types trivially have the same kind, and so we can just use <Tree *>: reflexivity for kind Tree *.

Finally, (5) and (6) are the two types that we are proving to be equal to each other.

This then explains the big difference between these two definitions:

requiresInstance = requireEmptyClass (Proxy @(ToTree ExampleFields))
requiresInstance = requireEmptyClass @(ToTree ExampleFields) Proxy

In the former, we are instantiating xs to (Branch ...) and we need to cast the proxy, which is basically free due to Proxy’s phantom type argument; in the latter, we are instantiating xs to (ToTree ...), and we need to cast the dictionary, which requires the full equality proof.

Incoherence

If a solution that relies on the precise nature of unification, instantiating type variables to evaluated types rather than unevaluated types, makes you a bit uneasy—I would agree. Moreover, even if we did accept that as unpleasant but necessary, we still haven’t really solved the problem. The issue is that

requireEmptyClass :: EmptyClass xs => Proxy xs -> ()
requireEmptyClass _ = ()

is a function we cannot abstract over: the moment we define something like

abstracted :: forall xs. EmptyClass (ToTree xs) => Proxy xs -> ()
abstracted _ = requireEmptyClass (Proxy @(ToTree xs))

in an attempt to make that ToTree call a responsibility of a library instead of use sites (after all, we wanted the tree representation to be an implementation detail), we are back to the original problem.

Let’s think a little harder about these roles. We finished the previous section with a remark that “(..) we need to cast the dictionary, which requires the full equality proofâ€�. But why is that? When we discussed roles above, we saw that the a type parameter in

data ShowType a = ShowType {
      showType :: Proxy a -> String
    }

has a phantom role; yet, when we define a type class

class ShowType a where
  showType :: Proxy a -> String

(which, after all, is much the same thing), a is assigned a nominal role, not a phantom role. The reason for this is that ghc insists on coherence (see Safe zero-cost coercions for Haskell, section 3.2, Preserving class coherence). Coherence simply means that there is only ever a single instance of a class for a specific type; it’s part of how ghc prevents ambiguity during instance resolution. We can override the role of the ShowType dictionary and declare it to be phantom

type role ShowType phantom

but we lose coherence:

data ShowTypeDict a where
  ShowTypeDict :: ShowType a => ShowTypeDict a

showWithDict :: Proxy a -> ShowTypeDict a -> String
showWithDict p ShowTypeDict = showType p

instance ShowType Int where showType _ = "Int"

showTypeInt :: ShowTypeDict Int
showTypeInt = ShowTypeDict

oops :: String
oops = showWithDict (Proxy @Bool) (coerce showTypeInt)

This means that the role annotation for ShowType requires the IncoherentInstances language pragma (there is currently no class-level pragma).

Solving the problem

Despite the problem with roles and potential incoherence discussed in the previous section, role annotations on classes cannot make instance resolution ambiguous or result in runtime type errors or segfaults. We do have to be cautious with the use of coerce, but we can shield the user from this through careful module exports. Indeed, we have used role annotations on type classes to our advantage before.

Specifically, we can redefine our EmptyClass as an internal (not-exported) class as follows:

class EmptyClass' (xs :: Tree Type) -- instances as before
type role EmptyClass' phantom

then define a wrapper class that does the translation from lists to trees:

class    EmptyClass' (ToTree xs) => EmptyClass (xs :: [Type])
instance EmptyClass' (ToTree xs) => EmptyClass (xs :: [Type])

requireEmptyClass :: EmptyClass xs => Proxy xs -> ()
requireEmptyClass _ = ()

Now the translation to a tree has become an implementation detail that users do not need to be aware of, whilst still avoiding (super)quadratic blow-up in core:

Constraint families

There is one final piece to the puzzle. Suppose we define a type family mapping types to constraints:

type family CF (a :: Type) :: Constraint

In the next session we will see a non-contrived example of this; for now, let’s just introduce a function that depends on CF a for no particular reason at all:

withCF :: CF a => Proxy a -> ()
withCF _ = ()

Finally, we provide an instance for HList:

type instance CF (HList xs) = EmptyClass (ToTree xs)

Now let’s measure the size of the core generated for a module containing a single call

satisfyCF :: ()
satisfyCF = withCF (Proxy @(HList ExampleFields))

Sigh.

Shallow thinking

In section Proxy versus type argument above, we saw that when we call

requireEmptyClass @(Branch _ _ _) (Proxy @(ToTree ExampleFields))

we construct a proof Ï€ :: Proxy (ToTree ...) ~ Proxy (Branch ...), which then gets simplified. We didn’t spell out in detail how that simplification happens though, so let’s do that now.

As mentioned above, the type checker always works with nominal equality. This means that the proof constructed by the type checker is actually Ï€ :: Proxy (ToTree ...) ~N Proxy (Branch ...). Whenever we cast something in core, however, we want a proof of representational equality. The coercion language has an explicit constructor for this⁸, so we could construct the proof

sub π :: Proxy (ToTree ...) ~R Proxy (Branch ...)

However, the function that constructs this proof first takes a look: if it is a constructing an equality proof T π' (i.e., an appeal to congruence for type T, applied to some proof Ï€'), where T has an argument with a phantom role, it replaces the proof (Ï€') with a universal coercion instead. This also happens when we construct a proof that EmptyClass (ToTree ...) ~R EmptyClass (Branch ...) (like in section Solving the problem), provided that the argument to EmptyClass is declared to have a phantom role.

Why doesn’t that happen here? When we call function withCF we need to construct evidence for CF (HList ExampleFields). Just like before, this means we must first evaluate this to EmptyClass (Branch ..), resulting in a proof of nominal equality Ï€ :: CF .. ~N EmptyClass (Branch ..). We then need to change this into a proof of representational equality to use as an argument to cast. However, where before Ï€ looked like Proxy π' or EmptyClass π', we now have a proof that looks like

  D:R:CFHList[0] <'[T 0, T 1, .., T 9]>_N
; EmptyClass π'

which first proves that CF (HList ..) ~ EmptyClass (ToTree ..), and only then proves that EmptyClass (ToTree ..) ~ EmptyClass (Branch ..). The function that attempts the proof simplification only looks at the top-level of the proof, and therefore does not notice an opportunity for simplification here and simply defaults to using sub π.

The function does not traverse the entire proof because doing so at every point during compilation could be prohibitively expensive. Instead, it does cheap checks only, leaving the rest to be cleaned up by coercion optimization. Coercion optimization is part of the “very simple optimizerâ€�, which runs even with -O0 (unless explicitly disabled with -fno-opt-coercion). In this particular example, coercion optimization will replace the proof (Ï€') by a universal coercion, but it will only do so later in the compilation pipeline; better to reduce the size of the core sooner rather than later. It’s also not entirely clear if it will always be able to do so, especially also because the coercion optimiser can make things significantly worse in some cases, and so it may be scaled back in the future. I think it’s preferable not to depend on it.

Avoiding deep normalization

As we saw, when we call

withCF (Proxy @(HList ExampleFields))

the type checker evaluates CF (HList ExampleFields) all the way to EmptyClass (Branch ...): although there is ghc ticket proposing to change this, at present whenever ghc evaluates a type, it evaluates it all the way. For our use case this is frustrating: if ghc were to rewrite CF (HList ..) to ExampleFields (ToTree ..) (with a tiny proof: just one rule application), we would then be back where we were in section Solving the problem, and we’d avoid the quadratic blow-up. Can we make ghc stop evaluating earlier? Yes, sort of. If instead of

type instance CF (HList xs) = EmptyClass (ToTree xs)

we say

class    EmptyClass (ToTree xs) => CF_HList xs
instance EmptyClass (ToTree xs) => CF_HList xs

type instance CF (HList xs) = CF_HList xs

then CF (HList xs) simply gets rewritten (in one step) to CF_HList xs, which contains no further type family applications. Now the type checker needs to check that CF_HList ExampleFields is satisfied, which will match the above instance, and hence it must check that EmptyClass (ToTree ExampleFields) is satisfied. Now, however, we really are back in the situation from section Solving the problem, and the size of our core looks good again:

Putting it all together: Generic instance for HList

Let’s put theory into practice and give a Generic instance for HList, of course avoiding quadratic blow-up in the process. We will use the Generic class from the large-records library, discussed at length in part 1.

The first problem we have to solve is that when giving a Generic instance for some type a, we need to choose a constraint

Constraints a c :: (Type -> Constraint) -> Constraint

such that when Constraints a c is satisfied, we can get a type class dictionary for c for every field in the record:

class Generic a where
  -- | @Constraints a c@ means "all fields of @a@ satisfy @c@"
  type Constraints a (c :: Type -> Constraint) :: Constraint

  -- | Construct vector of dictionaries, one for each field of the record
  dict :: Constraints a c => Proxy c -> Rep (Dict c) a

  -- .. other class members ..

Recall that Rep (Dict c) a is a vector containing a Dict c x for every field of type x in the record. Since we are avoiding heterogenous data structures (due to the large type annotations), we effectively need to write a function

hlistDict :: Constraints a c => Proxy a -> [Dict c Any]

Let’s tackle this in quite a general way, so that we can reuse what we develop here for the next problem as well. We have a type-level list of types of the elements of the HList, which we can translate to a type-level tree of types. We then need to reflect this type-level tree to a term-level tree with values of some type f Any (in this example, f ~ Dict c). We will delegate reflection of the values in the tree to a separate class:

class ReflectOne (f :: Type -> Type) (x :: Type) where
  reflectOne :: Proxy x -> f Any

class ReflectTree (f :: Type -> Type) (xs :: Tree Type) where
  reflectTree :: Proxy xs -> Tree (f Any)

type role ReflectTree nominal phantom -- critical!

Finally, we can then flatten that tree into a list, in such a way that it reconstructs the order of the list (i.e., it’s a term-level inverse to the ToTree type family):

treeToList :: Tree a -> [a]

The instances for ReflectTree are easy. For example, here is the instance for One:

instance ReflectOne f x => ReflectTree f ('One x) where
  reflectTree _ = One (reflectOne (Proxy @x))

The other instances for ReflectTree follow the same structure (the full source code can be found in the large-records test suite). It remains only to define a ReflectOne instance for our current specific use case:

instance c a => ReflectOne (Dict c) (a :: Type) where
  reflectOne _ = unsafeCoerce (Dict :: Dict c a)

With this definition, a constraint ReflectTree (Dict c) (ToTree xs) for a specific list of xs will result in a c x constraint for every x in xs, as expected. We are now ready to give a partial implementation of the Generic class:

hlistDict :: forall c (xs :: [Type]).
     ReflectTree (Dict c) (ToTree xs)
  => Proxy xs -> [Dict c Any]
hlistDict _ = treeToList $ reflectTree (Proxy @(ToTree xs))

class    ReflectTree (Dict c) (ToTree xs) => Constraints_HList xs c
instance ReflectTree (Dict c) (ToTree xs) => Constraints_HList xs c

instance Generic (HList xs) where
  type Constraints (HList xs) = Constraints_HList xs
  dict _ = Rep.unsafeFromListAny $ hlistDict (Proxy @xs)

The other problem that we need to solve is that we need to construct field metadata for every field in the record. Our (over)simplified “anonymous record� representation does not have field names, so we need to make them up from the type names. Assuming some type family

type family ShowType (a :: Type) :: Symbol

we can construct this metadata in much the same way that we constructed the dictionaries:

instance KnownSymbol (ShowType a) => ReflectOne FieldMetadata (a :: Type) where
  reflectOne _ = FieldMetadata (Proxy @(ShowType a)) FieldLazy

instance ReflectTree FieldMetadata (ToTree xs) => Generic (HList xs) where
  metadata _ = Metadata {
        recordName          = "Record"
      , recordConstructor   = "MkRecord"
      , recordSize          = length fields
      , recordFieldMetadata = Rep.unsafeFromListAny fields
      }
    where
      fields :: [FieldMetadata Any]
      fields = treeToList $ reflectTree (Proxy @(ToTree xs))

The graph below compares the size of the generated core between a straight-forward integration with generics-sop and two integrations with large-records, one in which the ReflectTree parameter has its inferred nominal role, and one with the phantom role override:

Both the generics-sop integration and the nominal large-records integration are O(n²). The constant factors are worse for generics-sop, however, because it suffers from both the problems described in part 1 of this blog as well as the problems described in this part 2. The nominal large-records integration only suffers from the problems described in part 2, which are avoided by the O(n log n) phantom integration.

TL;DR: Advice

We considered a lot of deeply technical detail in this blog post, but I think it can be condensed into two simple rules. To reduce the size of the generated core code:

1. Use instance induction only with balanced data structures.
2. Use expensive type families only in phantom contexts.

where “phantom context� is short-hand for “as an argument to a datatype, where that argument has a phantom role�. The table below summarizes the examples we considered in this blog post.

Don’t	Do
instance C xs => instance C (x ': xs)	instance (C l, C r) => instance C ('Branch l r)
foo @(F xs) Proxy	foo (Proxy @(F xs))
type role Cls nominal	type role Cls phantom Use with caution: requires IncoherentInstances
type instance F a = Expensive a	type instance F a = ClassAlias a (for F a :: Constraint)

Conclusions

This work was done in the context of trying to improve the compilation time of Juspay’s code base. When we first started analysing why Juspay was suffering from such long compilation times, we realized that a large part of the problem was due to the large core size generated by ghc when using large records, quadratic in the number of record fields. We therefore developed the large-records library, which offers support for records which guarantees to result in core code that is linear in the size of the record. A first integration attempt showed that this improved compilation time by roughly 30%, although this can probably be tweaked a little further.

As explained in MonadFix’s blog post Transpiling a large PureScript codebase into Haskell, part 2: Records are trouble, however, some of the records in the code base are anonymous records, and for these the large-records library is not (directly) applicable, and instead, MonadFix is using their own library jrec.

An analysis of the integration with large-records revealed however that these large anonymous records are causing similar problems as the named records did. Amongst the 13 most expensive modules (in terms of compilation time), 5 modules suffered from huge coercions, with less extreme examples elsewhere in the codebase. In one particularly bad example, one function contained coercion terms totalling nearly 2,000,000 AST nodes! (The other problem that stood out was due to large enumerations, not something I’ve thought much about yet.)

We have certainly not resolved all sources of quadratic core code for anonymous records in this blog post, nor have we attempted to integrate these ideas in jrec. However, the generic instance for anonymous records (using generics-sop generics) was particularly troublesome, and the ideas outlined above should at least solve that problem.

In general the problem of avoiding generating superlinear core is difficult and multifaceted:

• We need a way in ghc core to access and update record and type class dictionary fields without mentioning all fields in those records.
• We need a solution for all the type arguments. Perhaps one option is to improve control sharing at the type level; a long-standing problem. Perhaps we need more dramatic changes such as Scrap your type applications. Research from the world of dependently typed languages such as A dependently typed calculus with pattern matching and erasure inference may also provide insights.
• We need to improve the representation of coercions. The 2013 paper Evidence normalization in System FC introduced the concept of coercion optimization, but it is woefully inadequate in the presence of type family reduction. There is some ongoing work on improving the situation, as well as some proposals for specific stop-gap measures (e.g., see MR #6680) but there is still a long way to go.

Fortunately, ghc gives us just enough leeway that if we are very careful we can avoid the problem. That’s not a solution, obviously, but at least there are temporary work-arounds we can use.

Postscript: Pre-evaluating type families

If the evaluation of type families at compile time leads to large proofs, one for every step in the evaluation, perhaps we can improve matters by pre-evaluating these type families. For example, we could define ToTree as

type family ToTree (xs :: [Type]) :: Tree Type where
  ToTree '[]                       = 'Zero
  ToTree '[x0]                     = 'One x0
  ToTree '[x0, x1]                 = 'Two x0 x1
  ToTree '[x0, x1, x2]             = 'Branch x0 ('One x1)    ('One x2)
  ToTree '[x0, x1, x2, x3]         = 'Branch x0 ('Two x1 x3) ('One x2)
  ToTree '[x0, x1, x2, x3, x4]     = 'Branch x0 ('Two x1 x3) ('Two x2 x4)
  ToTree '[x0, x1, x2, x3, x4, x5] = 'Branch x0 ('Branch x1 ('One x3) ('One x5)) ('Two x2 x4)
  ...

perhaps (or perhaps not) with a final case that defaults to regular evaluation. Now ToTree xs can evaluate in a single step for any of the pre-computed cases. Somewhat ironically, in this case we’re better off without phantom contexts:

The universal coercion is now larger than the regular proof, because it records the full right-hand-side of the type family:

Univ(phantom phantom <Tree *>
  :: 'Branch
        (T 0)
        ('Branch (T 1) ('Two (T 3) (T 7)) ('Two (T 5) (T 9)))
        ('Branch (T 2) ('Two (T 4) (T 8)) ('One (T 6)))
   , ToTree '[T 0, T 1, T 2, T 3, T 4, T 5, T 6, T 7, T 8, T 9]))

The regular proof instead only records the rule that we’re applying:

D:R:ToTree[10] <T 0> <T 1> <T 2> <T 3> <T 4> <T 5> <T 6> <T 7> <T 8> <T 9>

Hence, the universal coercion is O(n log n), whereas the regular proof is O(n). Incidentally, this is also the reason why ghc doesn’t just always use universal coercions; in some cases the universal coercion can be significantly larger than the regular proof (the Rep type family of GHC.Generics being a typical example). The difference between O(n) and O(n log n) is of course significantly less important than the difference between O(n log n) and O(n²), especially since we anyway still have other O(n log n) factors, so if we can precompute type families like this, perhaps we can be less careful about roles.

However, this is only a viable option for certain type families. A full-blown anonymous records library will probably need to do quite a bit of type-level computation on the indices of the record. For example, the classical extensible records theory by Gaster and Jones depends crucially on a predicate lacks that checks that a particular field is not already present in a record. We might define this as

type family Lacks (x :: k) (xs :: [k]) :: Bool where
  Lacks x '[]       = 'True
  Lacks x (x ': xs) = 'False
  Lacks x (y ': xs) = Lacks x xs

It’s not clear to me how to pre-compute this type family in such a way that the right-hand side can evaluate in O(1) steps, without the type family needing O(n²) cases. We might attempt

type family Lacks (x :: k) (xs :: [k]) :: Bool where
  -- 0
  Lacks x '[] = 'True

  -- 1
  Lacks x '[x] = 'False
  Lacks x '[y] = 'True

  -- 2
  Lacks x '[x  , y2] = 'False
  Lacks x '[y1 , x ] = 'False
  Lacks x '[y1 , y2] = 'True

  -- 3
  Lacks x '[x,  y2 , y3] = 'False
  Lacks x '[y1, x  , y3] = 'False
  Lacks x '[y1, y2 , x ] = 'False
  Lacks x '[y1, y2 , y3] = 'True

  -- etc

but even if we only supported records with up to 200 fields, this would require over 20,000 cases. It’s tempting to try something like

type family Lacks (x :: k) (xs :: [k]) :: Bool where
  Lacks x []           = True
  Lacks x [y0]         = (x != y0)
  Lacks x [y0, y1]     = (x != y0) && (x != y1)
  Lacks x [y0, y1, y2] = (x != y0) && (x != y1) && (x != y2)
  ..

but that is not a solution (even supposing we had such an != operator): the right hand side still has O(n) operations, and so this would still result in proofs of O(n) size, just like the non pre-evaluated Lacks definition. Type families such as Sort would be more difficult still. Thus, although precomputation can in certain cases help avoid large proofs, and it’s a useful technique to have in the arsenal, I don’t think it’s a general solution.

Footnotes

---

1. The introduction of the Tree datatype is not strictly necessary. We could instead work exclusively with lists, and use Evens/Odds directly to split the list in two at each step. The introduction of Tree however makes this structure more obvious, and as a bonus leads to smaller core, although the difference is a constant factor only.↩ï¸�

2. This Tree data type is somewhat non-standard: we have values both at the leaves and in the branches, and we have leaves with zero, one or two values. Having values in both branches and leaves reduces the number of tree nodes by one half (leading to smaller core), which is an important enough improvement to warrant the minor additional complexity. The Two constructor only reduces the size the tree roughly by a further 4%, so not really worth it in general, but it’s useful for the sake of this blog post, as it keeps examples of trees a bit more manageable.↩ï¸�

3. Specifically, I made the following simplifications to the actual coercion proof:
   1. Drop the use of Sym, replacing Sym (a ; .. ; c) by (Sym c ; .. ; Sym a) and Sym c by simply c for atomic axioms c.
   2. Appeal to transitivity to replace a ; (b ; c) by a ; b ; c
   3. Drop all explicit use of congruence, replacing T c by simply c, whenever T has a single argument.
   4. As a final step, reverse the order of the proof; in this case at least, ghc seemed to reason backwards from the result of the type family application, but it’s more intuitive to reason forwards instead.↩ï¸�

4. See Master Theorem, case 3: Work to split/recombine a problem dominates subproblems.↩�

5. Roles were first described in Generative Type Abstraction and Type-level Computation. Phantom roles were introduced in Safe zero-cost coercions for Haskell.↩�

6. Safe zero-cost coercions for Haskell does not talk about this in great detail, but does mention it. See Fig 5, “Formation rules for coercionsâ€�, rule Co_Phantom, as well as the (extremely brief) section 4.2.2., “Phantom equality relates all typesâ€�. The paper does not use the terminology “universal coercionâ€�.↩ï¸�

7. Confusingly the pretty-printer uses a special syntax for a universal unsafe coercion, using UnsafeCoinstead of Univ.↩ï¸�

8. Safe zero-cost coercions for Haskell, section 4.2.1: Nominal equality implies representational equality.↩�

by edsko, adam at October 20, 2021 12:00 AM

Initial and final encodings of free monads

Posted on October 20, 2021

Free monads are often introduced as an algebraic data type, an initial encoding:

data Free f a = Pure a | Free (f (Free f a))

Thanks to that, the term “free monads” tends to be confused with that encoding, even though “free monads” originally refers to a representation-independent idea. Dually, there is a final encoding of free monads:

type Free' f a = (forall m. MonadFree f m => m a)

where MonadFree is the following class:

class Monad m => MonadFree f m where
  free :: f (m a) -> m a

The two types Free and Free' are isomorphic. An explanation a posteriori is that free monads are unique up to isomorphism. In this post, we will prove that they are isomorphic more directly,¹ in Coq.

In other words, there are two functions:

fromFree' :: Free' f a -> Free f a
toFree' :: Free f a -> Free' f a

such that, for all u :: Free f a,

fromFree' (toFree' u) = u  -- easy

and for all u :: Free' f a,

toFree' (fromFree' u) = u  -- hard

(Also, these functions are monad morphisms.)

The second equation is hard to prove because it relies on a subtle fact about polymorphism. If you have a polymorphic function forall m ..., it can only interact with m via operations provided as parameters—in the MonadFree dictionary. The equation crashes down if you can perform some kind of case analysis on types, such as isinstanceof in certain languages. This idea is subtle because, how do you turn this negative property “does not use isinstanceof” into a positive, useful fact about the functions of a language?

Parametricity is the name given to such properties. You can get a good intuition for it with some practice. For example, most people can convince themselves that forall a. a -> a is only inhabited by the identity function. But formalizing it so you can validate your intuition is a more mysterious art.

Proof sketch

First, unfolding some definitions, the equation we want to prove will simplify to the following:

foldFree (u @(Free f)) = u @m

where u :: forall m. MonadFree f m => m a is specialized at Free f on the left, at an arbitrary m on the right, and foldFree :: Free f a -> m a is a certain function we do not need to look into for now.

The main idea is that those different specializations of u are related by a parametricity theorem (aka. free theorem).

For all monads m1, m2 that are instances of MonadFree f, and for any relation r between m1 and m2, if r satisfies $CERTAIN_CONDITIONS, then r relates u @m1 and u @m2.

In this case, we will let r relate u1 :: Free f a and u2 :: m a when:

foldFree u1 = u2

As it turns out, r will satisfy $CERTAIN_CONDITIONS, so that the parametricity theorem above applies. This yields exactly the desired conclusion:

foldFree (u @(Free f)) = u @m

It is going to be a gnarly exposition of definitions before we can even get to the proof, and the only reason I can think of to stick around is morbid curiosity. But I had the proof and I wanted to do something with it.²

Formalization in Coq

Imports and setting options

From Coq Require Import Morphisms.

Set Implicit Arguments.
Set Contextual Implicit.

Initial free monads

Right off the bat, the first hurdle is that we cannot actually write the initial Free in Coq. To guarantee that all functions terminate and to prevent logical inconsistencies, Coq imposes restrictions about what recursive types can be defined. Indeed, Free could be used to construct an infinite loop by instantiating it with a contravariant functor f. The following snippet shows how we can inhabit the empty type Void, using only non-recursive definitions, so it’s fair to put the blame on Free:

newtype Cofun b a = Cofun (a -> b)

omicron :: Free (Cofun Void) Void -> Void
omicron (Pure y) = y
omicron (Free (Cofun z)) = z (Free (Cofun z))

omega :: Void
omega = omicron (Free (Cofun omicron))

To bypass that issue, we can tweak the definition of Free into what you might know as the freer monad, or the operational monad. The key difference is that the recursive occurrence of Free f a is no longer under an abstract f, but a concrete (->) instead.

Inductive Free (f : Type -> Type) (a : Type) : Type :=
| Pure : a -> Free f a
| Bind : forall e, f e -> (e -> Free f a) -> Free f a
.

Digression on containers

With that definition, it is no longer necessary for f to be a functor—it’s even undesirable because of size issues. Instead, f should rather be thought of as a type of “shapes”, containing “positions” of type e, and that induces a functor by assigning values to those positions (via the function e -> Free f a here); such an f is also known as a “container”.

For example, the Maybe functor consists of two “shapes”: Nothing, with no positions (indexed by Void), and Just, with one position (indexed by ()). Those shapes are defined by the following GADT, the Maybe container:

data PreMaybe _ where
  Nothing_ :: PreMaybe Void
  Just_ :: PreMaybe ()

A container extends into a functor, using a construction that some call Coyoneda:

data Maybe' a where
  MkMaybe' :: forall a e. PreMaybe e -> (e -> a) -> Maybe' a

data Coyoneda f a where
  Coyoneda :: forall f a e. f e -> (e -> a) -> Coyoneda f a

Freer f a (where Freer is called Free here in Coq) coincides with Free (Coyoneda f) a (for the original definition of Free at the top). If f is already a functor, then it is observationally equivalent to Coyoneda f.

Monad and MonadFree

The Monad class hides no surprises. For simplicity we skip the Functor and Applicative classes. Like in C, return is a keyword in Coq, so we have to settle for another name.

Class Monad (m : Type -> Type) : Type :=
  { pure : forall {a}, a -> m a
  ; bind : forall {a b}, m a -> (a -> m b) -> m b
  }.
(* The braces after `forall` make the arguments implicit. *)

Our MonadFree class below is different than in Haskell because of the switch from functors to containers (see previous section). In the original MonadFree, the method free takes an argument of type f (m a), where the idea is to “interpret” the outer layer f, and “carry on” with a continuation m a. Containers encode that outer layer without the continuation.³

Class MonadFree {f m : Type -> Type} `{Monad m} : Type :=
  { free : forall {x}, f x -> m x }.

(* Some more implicit arguments nonsense. *)
Arguments MonadFree f m {_}.

Here comes the final encoding of free monads. The resemblance to the Haskell code above should be apparent in spite of some funny syntax.

Definition Free' (f : Type -> Type) (a : Type) : Type :=
  forall m `(MonadFree f m), m a.

Type classes in Coq are simply types with some extra type inference rules to infer dictionaries. Thus, the definition of Free' actually desugars to a function type forall m, Monad m -> MonadFree f m -> m a. A value u : Free' f a is a function whose arguments are a type constructor m, followed by two dictionaries of the Monad and MonadFree classes. We specialize u to a monad m by writing u m _ _, applying u to the type constructor m and two holes (underscores) for the dictionaries, whose contents will be inferred via type class resolution. See for example fromFree' below.

While we’re at it, we can define the instances of Monad and MonadFree for the initial encoding Free.

Fixpoint bindFree {f a b} (u : Free f a) (k : a -> Free f b) : Free f b :=
  match u with
  | Pure a => k a
  | Bind e h => Bind e (fun x => bindFree (h x) k)
  end.

Instance Monad_Free f : Monad (Free f) :=
  {| pure := @Pure f
  ;  bind := @bindFree f
  |}.

Instance MonadFree_Free f : MonadFree f (Free f) :=
  {| free A e := Bind e (fun a => Pure a)
  |}.

Interpretation of free monads

To show that those monads are equivalent, we must exhibit a mapping going both ways.

The easy direction is from the final Free' to the initial Free: with the above instances of Monad and MonadFree, just monomorphize the polymorph.

Definition fromFree' {f a} : Free' f a -> Free f a :=
  fun u => u (Free f) _ _.

The other direction is obtained via a fold of Free f, which allows us to interpret it in any instance of MonadFree f: replace Bind with bind, interpret the first operand with free, and recurse in the second operand.

Fixpoint foldFree {f m a} `{MonadFree f m} (u : Free f a) : m a :=
  match u with
  | Pure a => pure a
  | Bind e k => bind (free e) (fun x => foldFree (k x))
  end.

Definition toFree' {f a} : Free f a -> Free' f a :=
  fun u M _ _ => foldFree u.

Equality

In everyday mathematics, equality is a self-evident notion that we take for granted. But if you want to minimize your logical foundations, you do not need equality as a primitive. Equations are just equivalences, where the equivalence relation is kept implicit.

Who even decides what the rules for reasoning about equality are anyway? You decide, by picking the underlying equivalence relation. ⁴

Here is a class for equality. It is similar to Eq in Haskell, but it is propositional (a -> a -> Prop) rather than boolean (a -> a -> Bool), meaning that equality doesn’t have to be decidable.

Class PropEq (a : Type) : Type :=
  propeq : a -> a -> Prop.

Notation "x = y" := (propeq x y) : type_scope.
Notation "_ = _" was already used in scope type_scope.
[notation-overridden,parsing]

For example, for inductive types, a common equivalence can be defined as another inductive type which equates constructors and their fields recursively. Here it is for Free:

Inductive eq_Free f a : PropEq (Free f a) :=
| eq_Free_Pure x : eq_Free (Pure x) (Pure x)
| eq_Free_Bind p (e : f p) k1 k2
  : (forall x, eq_Free (k1 x) (k2 x)) ->
    eq_Free (Bind e k1) (Bind e k2)
.

(* Register it as an instance of PropEq *)
Existing Instance eq_Free.

Having defined equality for Free, we can state and prove one half of the isomorphism between Free and Free'.

Theorem to_from f a (u : Free f a)
  : fromFree' (toFree' u) = u.
f: Type -> Type
a: Type
u: Free f a
fromFree' (toFree' u) = u

The proof is straightforward by induction, case analysis (which is performed as part of induction), and simplification.

Proof.
f: Type -> Type
a: Type
u: Free f a
fromFree' (toFree' u) = u
  induction u.
f: Type -> Type
a: Type
a0: a
fromFree' (toFree' (Pure a0)) = Pure a0
f: Type -> Type
a, e: Type
f0: f e
f1: e -> Free f a
H: forall e : e, fromFree' (toFree' (f1 e)) = f1 e
fromFree' (toFree' (Bind f0 f1)) = Bind f0 f1 all: cbn.
f: Type -> Type
a: Type
a0: a
Pure a0 = Pure a0
f: Type -> Type
a, e: Type
f0: f e
f1: e -> Free f a
H: forall e : e, fromFree' (toFree' (f1 e)) = f1 e
Bind f0 (fun x : e => foldFree (f1 x)) = Bind f0 f1 all: constructor; auto.
Qed.

Equality on final encodings, naive attempts

To state the other half of the isomorphism (toFree' (fromFree' u) = u), it is less obvious what the right equivalence relation on Free' should be. When are two polymorphic values u1, u2 : forall m `(MonadFree f m), m a equal? A fair starting point is that all of their specializations must be equal. “Equality” requires an instance of PropEq, which must be introduced as an extra parameter.

(* u1 and u2 are "equal" when all of their specializations
   (u1 m _ _) and (u2 m _ _) are equal. *)
Definition eq_Free'_very_naive f a (u1 u2 : Free' f a) : Prop :=
  forall m `(MonadFree f m) `(forall x, PropEq (m x)),
    u1 m _ _ = u2 m _ _.

That definition is flagrantly inadequate: so far, a PropEq instance can be any relation, including the empty relation (which never holds), and the Monad instance (as a superclass of MonadFree) might be unlawful. In our desired theorem, toFree' (fromFree' u) = u, the two sides use a priori different combinations of bind and pure, so we expect to rely on laws to be able to rewrite one side into the other.

In programming, we aren’t used to proving that implementations satisfy their laws, so there is always the possibility that a Monad instance is unlawful. In math, the laws are in the definitions; if something doesn’t satisfy the monad laws, it’s not a monad. Let’s irk some mathematicians and say that a lawful monad is a monad that satisfies the monad laws. Thus we will have one Monad class for the operations only, and one LawfulMonad class for the laws they should satisfy. Separating code and proofs that way helps to organize things. Code is often much simpler than the proofs about it, since the latter necessarily involves dependent types.

Class LawfulMonad {m} `{Monad m} `{forall a, PropEq (m a)} : Prop :=
  { Equivalence_LawfulMonad :> forall a, Equivalence (propeq (a := m a))
  ; propeq_bind : forall a b (u u' : m a) (k k' : a -> m b),
      u = u' -> (forall x, k x = k' x) -> bind u k = bind u' k'
  ; bind_pure : forall a (u : m a),
      bind u (pure (a := a)) = u
  ; pure_bind : forall a b (x : a) (k : a -> m b),
      bind (pure x) k = k x
  ; bind_bind : forall a b c (u : m a) (k : a -> m b) (h : b -> m c),
      bind (bind u k) h = bind u (fun x => bind (k x) h)
  }.

The three monad laws should be familiar (bind_pure, pure_bind, bind_bind). In those equations, “=” denotes a particular equivalence relation, which is now a parameter/superclass of the class. Once you give up on equality as a primitive notion, algebraic structures must now carry their own equivalence relations. The requirement that it is an equivalence relation also becomes an explicit law (Equivalence_LawfulMonad), and we expect that operations (in this case, bind) preserve the equivalence (propeq_bind). Practically speaking, that last fact allows us to rewrite subexpressions locally, otherwise we could only apply the monad laws at the root of an expression.

A less naive equivalence on Free' is thus to restrict the quantification to lawful instances:

Definition eq_Free'_naive f a (u1 u2 : Free' f a) : Prop :=
  forall m `(MonadFree f m) `(forall x, PropEq (m x)) `(!LawfulMonad (m := m)),
    u1 m _ _ = u2 m _ _.

That is a quite reasonable definition of equivalence for Free'. In other circumstances, it could have been useful. Unfortunately, it is too strong here: we cannot prove the equation toFree' (fromFree' u) = u with that interpretation of =. Or at least I couldn’t figure out a solution. We will need more assumptions to be able to apply the parametricity theorem of the type Free'. To get there, we must formalize Reynolds’ relational interpretation of types.

Types as relations

The core technical idea in Reynolds’ take on parametricity is to interpret a type t as a relation Rt : t -> t -> Prop. Then, the parametricity theorem is that all terms x : t are related to themselves by Rt (Rt x x is true). If t is a polymorphic type, that theorem connects different specializations of a same term x : t, and that allows us to formalize arguments that rely on “parametricity” as a vague idea.

For example, if t = (forall a, a -> a), then Rt is the following relation, which says that two functions f and f' are related if for any relation Ra (on any types), f and f' send related inputs (Ra x x') to related outputs (Ra (f a x) (f' a' x')).

Rt f f' =
  forall a a' (Ra : a -> a' -> Prop),
  forall x x', Ra x x' -> Ra (f a x) (f' a' x')

If we set Ra x x' to mean “x equals an arbitrary constant z0” (ignoring x', i.e., treating Ra as a unary relation), the above relation Rt amounts to saying that f z0 = z0, from which we deduce that f must be the identity function.

The fact that Rt is a relation is not particularly meaningful to the parametricity theorem, where terms are simply related to themselves, but it is a feature of the construction of Rt: the relation for a composite type t1 -> t2 combines the relations for the components t1 and t2, and we could not get the same result with only unary predicates throughout.⁵ More formally, we define a relation R[t] by induction on t, between the types t and t', where t' is the result of renaming all variables x to x' in t (including binders). The two most interesting cases are:

• t starts with a quantifier t = forall a, _, for a type variable a. Then the relation R[forall a, _] between the polymorphic f and f' takes two arbitrary types a and a' to specialize f and f' with, and a relation Ra : a -> a' -> Prop, and relates f a and f' a' (recursively), using Ra whenever recursion reaches a variable a.

• t is an arrow t1 -> t2, then R[t1 -> t2] relates functions that send related inputs to related outputs.

In summary:

R[forall a, t](f, f') = forall a a' Ra, R[t](f a)(f' a')
R[a](f, f')           = Ra(f, f')
                        -- Ra should be in scope when a is in scope.
R[t1 -> t2](f, f')    = forall x x', R[t1](x, x') -> R[t2](f x, f' x')

That explanation was completely unhygienic, but refer to Reynolds’ paper or Wadler’s Theorems for free! for more formal details.

For sums (Either/sum) and products ((,)/prod), two values are related if they start with the same constructor, and their fields are related (recursively). This can be deduced from the rules above applied to the Church encodings of sums and products.

Type constructors as relation transformers

While types t : Type are associated to relations Rt : t -> t -> Prop, type constructors m : Type -> Type are associated to relation transformers (functions on relations) Rm : forall a a', (a -> a' -> Prop) -> (m a -> m a' -> Prop). It is usually clear what’s what from the context, so we will often refer to “relation transformers” as just “relations”.

For example, the initial Free f a type gets interpreted to the relation RFree Rf Ra defined as follows. Two values u1 : Free f1 a1 and u2 : Free f2 a2 are related by RFree if either:

• u1 = Pure x1, u2 = Pure x2, and x1 and x2 are related (by Ra); or
• u1 = Bind e1 k1, u2 = Bind e2 k2, e1 and e2 are related, and k1 and k2 are related (recursively).

We thus have one rule for each constructor (Pure and Bind) in which we relate each field (Ra x1 x2 in RFree_Pure; Rf _ _ _ y1 y2 and RFree Rf Ra (k1 x1) (k2 x2) in RFree_Bind). Let us also remark that the existential type e in Bind becomes an existential relation Re in RFree_Bind.

Inductive RFree {f₁ f₂ : Type -> Type}
    (Rf : forall a₁ a₂ : Type, (a₁ -> a₂ -> Prop) -> f₁ a₁ -> f₂ a₂ -> Prop)
    {a₁ a₂ : Type} (Ra : a₁ -> a₂ -> Prop) : Free f₁ a₁ -> Free f₂ a₂ -> Prop :=
  | RFree_Pure : forall (x₁ : a₁) (x₂ : a₂),
      Ra x₁ x₂ -> RFree Rf Ra (Pure x₁) (Pure x₂)
  | RFree_Bind : forall (e₁ e₂ : Type) (Re : e₁ -> e₂ -> Prop) (y₁ : f₁ e₁) (y₂ : f₂ e₂),
      Rf e₁ e₂ Re y₁ y₂ ->
      forall (k₁ : e₁ -> Free f₁ a₁) (k₂ : e₂ -> Free f₂ a₂),
      (forall (x₁ : e₁) (x₂ : e₂),
        Re x₁ x₂ -> RFree Rf Ra (k₁ x₁) (k₂ x₂)) ->
      RFree Rf Ra (Bind y₁ k₁) (Bind y₂ k₂).

Inductive relations such as RFree, indexed by types with existential quantifications such as Free, are a little terrible to work with out-of-the-box—especially if you’re allergic to UIP. Little “inversion lemmas” like the following make them a bit nicer by reexpressing those relations in terms of some standard building blocks which leave less of a mess when decomposed.

Definition inv_RFree {f₁ f₂} Rf {a₁ a₂} Ra (u₁ : Free f₁ a₁) (u₂ : Free f₂ a₂)
  : RFree Rf Ra u₁ u₂ ->
    match u₁, u₂ return Prop with
    | Pure a₁, Pure a₂ => Ra a₁ a₂
    | Bind y₁ k₁, Bind y₂ k₂ =>
      exists Re, Rf _ _ Re y₁ y₂ /\
        (forall x₁ x₂, Re x₁ x₂ -> RFree Rf Ra (k₁ x₁) (k₂ x₂))
    | _, _ => False
    end.
f₁, f₂: Type -> Type
Rf: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> f₁ a₁ -> f₂ a₂ -> Prop
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
u₁: Free f₁ a₁
u₂: Free f₂ a₂
RFree Rf Ra u₁ u₂ ->
match u₁ with
| Pure a₁ =>
    match u₂ with
    | Pure a₂ => Ra a₁ a₂
    | Bind _ _ => False
    end
| @Bind _ _ e y₁ k₁ =>
    match u₂ with
    | Pure _ => False
    | @Bind _ _ e0 y₂ k₂ =>
        exists Re : e -> e0 -> Prop,
          Rf e e0 Re y₁ y₂ /\
          (forall (x₁ : e) (x₂ : e0),
           Re x₁ x₂ -> RFree Rf Ra (k₁ x₁) (k₂ x₂))
    end
end
Proof.
f₁, f₂: Type -> Type
Rf: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> f₁ a₁ -> f₂ a₂ -> Prop
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
u₁: Free f₁ a₁
u₂: Free f₂ a₂
RFree Rf Ra u₁ u₂ ->
match u₁ with
| Pure a₁ =>
    match u₂ with
    | Pure a₂ => Ra a₁ a₂
    | Bind _ _ => False
    end
| @Bind _ _ e y₁ k₁ =>
    match u₂ with
    | Pure _ => False
    | @Bind _ _ e0 y₂ k₂ =>
        exists Re : e -> e0 -> Prop,
          Rf e e0 Re y₁ y₂ /\
          (forall (x₁ : e) (x₂ : e0),
           Re x₁ x₂ -> RFree Rf Ra (k₁ x₁) (k₂ x₂))
    end
end
  intros []; eauto.
Qed.

Type classes, which are (record) types, also get interpreted in the same way. Since Monad is parameterized by a type constructor m, the relation RMonad between Monad instances is parameterized by a relation between two type constructors m1 and m2. Two instances of Monad, i.e., two values of type Monad m for some m, are related if their respective fields, i.e., pure and bind, are related. pure and bind are functions, so two instances are related when they send related inputs to related outputs.

Record RMonad (m₁ m₂ : Type -> Type)
    (Rm : forall a₁ a₂ : Type, (a₁ -> a₂ -> Prop) -> m₁ a₁ -> m₂ a₂ -> Prop)
    `{Monad m₁} `{Monad m₂} : Prop :=
  { RMonad_pure : forall (t₁ t₂ : Type) (Rt : t₁ -> t₂ -> Prop) (x₁ : t₁) (x₂ : t₂),
      Rt x₁ x₂ -> Rm t₁ t₂ Rt (pure x₁) (pure x₂)
  ; RMonad_bind : forall (t₁ t₂ : Type) (Rt : t₁ -> t₂ -> Prop) 
      (u₁ u₂ : Type) (Ru : u₁ -> u₂ -> Prop) (x₁ : m₁ t₁) (x₂ : m₂ t₂),
      Rm t₁ t₂ Rt x₁ x₂ ->
      forall (k₁ : t₁ -> m₁ u₁) (k₂ : t₂ -> m₂ u₂),
      (forall (x₁ : t₁) (x₂ : t₂),
         Rt x₁ x₂ -> Rm u₁ u₂ Ru (k₁ x₁) (k₂ x₂)) ->
      Rm u₁ u₂ Ru (bind x₁ k₁) (bind x₂ k₂)
  }.

MonadFree also gets translated to a relation RMonadFree. Related inputs, related outputs.

Record RMonadFree (f₁ f₂ : Type -> Type)
    (Rf : forall a₁ a₂ : Type, (a₁ -> a₂ -> Prop) -> f₁ a₁ -> f₂ a₂ -> Prop)
    (m₁ m₂ : Type -> Type)
    (Rm : forall a₁ a₂ : Type, (a₁ -> a₂ -> Prop) -> m₁ a₁ -> m₂ a₂ -> Prop)
    `{MonadFree f₁ m₁} `{MonadFree f₂ m₂} : Prop :=
  { RMonadFree_free : forall (a₁ a₂ : Type) (Ra : a₁ -> a₂ -> Prop) (x₁ : f₁ a₁) (x₂ : f₂ a₂),
      Rf a₁ a₂ Ra x₁ x₂ -> Rm a₁ a₂ Ra (free x₁) (free x₂)
  }.

Note that RMonad and RMonadFree are “relation transformer transformers”, since they take relation transformers as arguments, to produce a relation between class dictionaries.

We can now finally translate the final Free' to a relation. Two values u1 : Free' f1 a1 and u2 : Free' f2 a2 are related if, for any two monads m1 and m2, with a relation transformer Rm, whose Monad and MonadFree instances are related by RMonad and RMonadFree, Rm relates u1 m1 _ _ and u2 m2 _ _.

Definition RFree' {f₁ f₂} Rf {a₁ a₂} Ra (u₁ : Free' f₁ a₁) (u₂ : Free' f₂ a₂) : Prop :=
  forall m₁ m₂ `(MonadFree f₁ m₁) `(MonadFree f₂ m₂) Rm
    (pm : RMonad Rm) (pf : RMonadFree Rf Rm),
    Rm _ _ Ra (u₁ m₁ _ _) (u₂ m₂ _ _).

The above translation of types into relations can be automated by a tool such as paramcoq. However paramcoq currently constructs relations in Type instead of Prop, which got me stuck in universe inconsistencies. That’s why I’m declaring Prop relations the manual way here.

The parametricity theorem says that any u : Free' f a is related to itself by RFree' (for some canonical relations on f and a). It is a theorem about the language Coq which we can’t prove within Coq. Rather than postulate it, we will simply add the required RFree' _ _ u u assumption to our proposition (from_to below). Given a concrete u, it should be straightforward to prove that assumption case-by-case in order to apply that proposition.

These “relation transformers” are a bit of a mouthful to spell out, and they’re usually guessable from the type constructor (f or m), so they deserve a class, that’s a higher-order counterpart to PropEq (like Eq1 is to Eq in Haskell).

Class PropEq1 (m : Type -> Type) : Type :=
  propeq1 : forall a₁ a₂, (a₁ -> a₂ -> Prop) -> m a₁ -> m a₂ -> Prop.

Given a PropEq1 m instance, we can apply it to the relation eq to get a plain relation which seems a decent enough default for PropEq (m a).

Instance PropEq_PropEq1 {m} `{PropEq1 m} {a} : PropEq (m a) := propeq1 eq.

Really lawful monads

We previously defined a “lawful monad” as a monad with an equivalence relation (PropEq (m a)). To use parametricity, we will also need a monad m to provide a relation transformer (PropEq1 m), which subsumes PropEq with the instance just above.⁶ This extra structure comes with additional laws, extending our idea of monads to “really lawful monads”.

Class Trans_PropEq1 {m} `{PropEq1 m} : Prop :=
  trans_propeq1 : forall a₁ a₂ (r : a₁ -> a₂ -> Prop) x₁ x₁' x₂ x₂',
    x₁ = x₁' -> propeq1 r x₁' x₂ -> x₂ = x₂' -> propeq1 r x₁ x₂'.

Class ReallyLawfulMonad m `{Monad m} `{PropEq1 m} : Prop :=
  { LawfulMonad_RLM :> LawfulMonad (m := m)
  ; Trans_PropEq1_RLM :> Trans_PropEq1 (m := m)
  ; RMonad_RLM : RMonad (propeq1 (m := m))
  }.

Class ReallyLawfulMonadFree f `{PropEq1 f} m `{MonadFree f m} `{PropEq1 m} : Prop :=
  { ReallyLawfulMonad_RLMF :> ReallyLawfulMonad (m := m)
  ; RMonadFree_RLMF : RMonadFree (propeq1 (m := f)) (propeq1 (m := m))
  }.

We inherit the LawfulMonad laws from before. The relations RMonad and RMonadFree, defined earlier, must relate m’s instances of Monad and MonadFree, for the artificial reason that that’s roughly what RFree' will require. We also add a generalized transitivity law, which allows us to rewrite either side of a heterogeneous relation propeq1 r using the homogeneous one = (which denotes propeq1 eq).

It’s worth noting that there is some redundancy here, that could be avoided with a bit of refactoring. That generalized transitivity law Trans_PropEq1 implies transitivity of =, which is part of the claim that = is an equivalence relation in LawfulMonad. And the bind component of RMonad implies propeq_bind in LawfulMonad, so these RMonad and RMonadFree laws can also be seen as generalizations of congruence laws to heterogeneous relations, making them somewhat less artificial than they may seem at first.

Restricting the definition of equality on the final free monad Free' to quantify only over really lawful monads yields the right notion of equality for our purposes, which is to prove the from_to theorem below, validating the isomorphism between Free and Free'.

Instance eq_Free' f `(PropEq1 f) a : PropEq (Free' f a) :=
  fun u₁ u₂ =>
    forall m `(MonadFree f m) `(PropEq1 m) `(!ReallyLawfulMonadFree (m := m)),
      u₁ m _ _ = u₂ m _ _.

---

Quickly, let’s get the following lemma out of the way, which says that foldFree commutes with bind. We’re really saying that foldFree is a monad morphism but no time to say it properly. The proof of the next lemma will need this, but it’s also nice to look at this on its own.

Lemma foldFree_bindFree {f m} `{MonadFree f m} `{forall a, PropEq (m a)} `{!LawfulMonad (m := m)}
    {a b} (u : Free f a) (k : a -> Free f b)
  : foldFree (bindFree u k) = bind (foldFree u) (fun x => foldFree (k x)).
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b: Type
u: Free f a
k: a -> Free f b
foldFree (bindFree u k) =
bind (foldFree u) (fun x : a => foldFree (k x))
Proof.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b: Type
u: Free f a
k: a -> Free f b
foldFree (bindFree u k) =
bind (foldFree u) (fun x : a => foldFree (k x))
  induction u; cbn [bindFree foldFree].
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b: Type
a0: a
k: a -> Free f b
foldFree (k a0) =
bind (pure a0) (fun x : a => foldFree (k x))
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b, e: Type
f0: f e
f1: e -> Free f a
k: a -> Free f b
H2: forall e : e,
foldFree (bindFree (f1 e) k) =
bind (foldFree (f1 e))
  (fun x : a => foldFree (k x))
bind (free f0)
  (fun x : e => foldFree (bindFree (f1 x) k)) =
bind (bind (free f0) (fun x : e => foldFree (f1 x)))
  (fun x : a => foldFree (k x))
  -
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b: Type
a0: a
k: a -> Free f b
foldFree (k a0) =
bind (pure a0) (fun x : a => foldFree (k x)) symmetry.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b: Type
a0: a
k: a -> Free f b
bind (pure a0) (fun x : a => foldFree (k x)) =
foldFree (k a0) apply pure_bind with (k0 := fun x => foldFree (k x)).
  -
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b, e: Type
f0: f e
f1: e -> Free f a
k: a -> Free f b
H2: forall e : e,
foldFree (bindFree (f1 e) k) =
bind (foldFree (f1 e))
  (fun x : a => foldFree (k x))
bind (free f0)
  (fun x : e => foldFree (bindFree (f1 x) k)) =
bind (bind (free f0) (fun x : e => foldFree (f1 x)))
  (fun x : a => foldFree (k x)) etransitivity; [ | symmetry; apply bind_bind ].
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b, e: Type
f0: f e
f1: e -> Free f a
k: a -> Free f b
H2: forall e : e,
foldFree (bindFree (f1 e) k) =
bind (foldFree (f1 e))
  (fun x : a => foldFree (k x))
bind (free f0)
  (fun x : e => foldFree (bindFree (f1 x) k)) =
bind (free f0)
  (fun x : e =>
   bind ((fun x0 : e => foldFree (f1 x0)) x)
     (fun x0 : a => foldFree (k x0)))
    eapply propeq_bind.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b, e: Type
f0: f e
f1: e -> Free f a
k: a -> Free f b
H2: forall e : e,
foldFree (bindFree (f1 e) k) =
bind (foldFree (f1 e))
  (fun x : a => foldFree (k x))
free f0 = free f0
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b, e: Type
f0: f e
f1: e -> Free f a
k: a -> Free f b
H2: forall e : e,
foldFree (bindFree (f1 e) k) =
bind (foldFree (f1 e))
  (fun x : a => foldFree (k x))
forall x : e,
foldFree (bindFree (f1 x) k) =
bind (foldFree (f1 x)) (fun x0 : a => foldFree (k x0))
    *
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b, e: Type
f0: f e
f1: e -> Free f a
k: a -> Free f b
H2: forall e : e,
foldFree (bindFree (f1 e) k) =
bind (foldFree (f1 e))
  (fun x : a => foldFree (k x))
free f0 = free f0 reflexivity.
    *
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: forall a : Type, PropEq (m a)
LawfulMonad0: LawfulMonad
a, b, e: Type
f0: f e
f1: e -> Free f a
k: a -> Free f b
H2: forall e : e,
foldFree (bindFree (f1 e) k) =
bind (foldFree (f1 e))
  (fun x : a => foldFree (k x))
forall x : e,
foldFree (bindFree (f1 x) k) =
bind (foldFree (f1 x)) (fun x0 : a => foldFree (k x0)) auto.
Qed.

Finally the proof

Our goal is to prove an equation in terms of eq_Free', which gives us a really lawful monad as an assumption. We open a section to set up the same context as that and to break down the proof into more digestible pieces.

Section ISOPROOF.

Context {f m} `{MonadFree f m} `{PropEq1 m} `{!ReallyLawfulMonad (m := m)}.

As outlined earlier, parametricity will yield an assumption RFree' _ _ u u, and we will specialize it with a relation R which relates u1 : Free f a and u2 : m a when foldFree u1 = u2. However, RFree' actually expects a relation transformer rather than a relation, so we instead define R to relate u1 : Free f a1 and u2 : Free f a2 when propeq1 Ra (foldFree u1) u2, where Ra is a relation given between a1 and a2.

Let R := (fun a₁ a₂ (Ra : a₁ -> a₂ -> Prop) u₁ u₂ => propeq1 Ra (foldFree u₁) u₂).

The following two lemmas are the “$CERTAIN_CONDITIONS” mentioned earlier, that R must satisfy, i.e., we prove that R, via RMonad (resp. RMonadFree), relates the Monad (resp. MonadFree) instances for Free f and m.

Lemma RMonad_foldFree : RMonad (m₁ := Free f) R.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
RMonad R
Proof.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
RMonad R
  constructor; intros.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
x₁: t₁
x₂: t₂
H2: Rt x₁ x₂
R Rt (pure x₁) (pure x₂)
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
u₁, u₂: Type
Ru: u₁ -> u₂ -> Prop
x₁: Free f t₁
x₂: m t₂
H2: R Rt x₁ x₂
k₁: t₁ -> Free f u₁
k₂: t₂ -> m u₂
H3: forall (x₁ : t₁) (x₂ : t₂),
Rt x₁ x₂ -> R Ru (k₁ x₁) (k₂ x₂)
R Ru (bind x₁ k₁) (bind x₂ k₂)
  -
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
x₁: t₁
x₂: t₂
H2: Rt x₁ x₂
R Rt (pure x₁) (pure x₂) cbn.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
x₁: t₁
x₂: t₂
H2: Rt x₁ x₂
R Rt (Pure x₁) (pure x₂) apply RMonad_RLM; auto.
  -
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
u₁, u₂: Type
Ru: u₁ -> u₂ -> Prop
x₁: Free f t₁
x₂: m t₂
H2: R Rt x₁ x₂
k₁: t₁ -> Free f u₁
k₂: t₂ -> m u₂
H3: forall (x₁ : t₁) (x₂ : t₂),
Rt x₁ x₂ -> R Ru (k₁ x₁) (k₂ x₂)
R Ru (bind x₁ k₁) (bind x₂ k₂) unfold R.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
u₁, u₂: Type
Ru: u₁ -> u₂ -> Prop
x₁: Free f t₁
x₂: m t₂
H2: R Rt x₁ x₂
k₁: t₁ -> Free f u₁
k₂: t₂ -> m u₂
H3: forall (x₁ : t₁) (x₂ : t₂),
Rt x₁ x₂ -> R Ru (k₁ x₁) (k₂ x₂)
propeq1 Ru (foldFree (bind x₁ k₁)) (bind x₂ k₂) eapply trans_propeq1.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
u₁, u₂: Type
Ru: u₁ -> u₂ -> Prop
x₁: Free f t₁
x₂: m t₂
H2: R Rt x₁ x₂
k₁: t₁ -> Free f u₁
k₂: t₂ -> m u₂
H3: forall (x₁ : t₁) (x₂ : t₂),
Rt x₁ x₂ -> R Ru (k₁ x₁) (k₂ x₂)
foldFree (bind x₁ k₁) = ?x₁'
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
u₁, u₂: Type
Ru: u₁ -> u₂ -> Prop
x₁: Free f t₁
x₂: m t₂
H2: R Rt x₁ x₂
k₁: t₁ -> Free f u₁
k₂: t₂ -> m u₂
H3: forall (x₁ : t₁) (x₂ : t₂),
Rt x₁ x₂ -> R Ru (k₁ x₁) (k₂ x₂)
propeq1 Ru ?x₁' ?x₂
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
u₁, u₂: Type
Ru: u₁ -> u₂ -> Prop
x₁: Free f t₁
x₂: m t₂
H2: R Rt x₁ x₂
k₁: t₁ -> Free f u₁
k₂: t₂ -> m u₂
H3: forall (x₁ : t₁) (x₂ : t₂),
Rt x₁ x₂ -> R Ru (k₁ x₁) (k₂ x₂)
?x₂ = bind x₂ k₂
    +
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
u₁, u₂: Type
Ru: u₁ -> u₂ -> Prop
x₁: Free f t₁
x₂: m t₂
H2: R Rt x₁ x₂
k₁: t₁ -> Free f u₁
k₂: t₂ -> m u₂
H3: forall (x₁ : t₁) (x₂ : t₂),
Rt x₁ x₂ -> R Ru (k₁ x₁) (k₂ x₂)
foldFree (bind x₁ k₁) = ?x₁' apply foldFree_bindFree.
    +
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
u₁, u₂: Type
Ru: u₁ -> u₂ -> Prop
x₁: Free f t₁
x₂: m t₂
H2: R Rt x₁ x₂
k₁: t₁ -> Free f u₁
k₂: t₂ -> m u₂
H3: forall (x₁ : t₁) (x₂ : t₂),
Rt x₁ x₂ -> R Ru (k₁ x₁) (k₂ x₂)
propeq1 Ru
  (bind (foldFree x₁) (fun x : t₁ => foldFree (k₁ x)))
  ?x₂ eapply RMonad_RLM; eauto.
    +
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
t₁, t₂: Type
Rt: t₁ -> t₂ -> Prop
u₁, u₂: Type
Ru: u₁ -> u₂ -> Prop
x₁: Free f t₁
x₂: m t₂
H2: R Rt x₁ x₂
k₁: t₁ -> Free f u₁
k₂: t₂ -> m u₂
H3: forall (x₁ : t₁) (x₂ : t₂),
Rt x₁ x₂ -> R Ru (k₁ x₁) (k₂ x₂)
bind x₂ k₂ = bind x₂ k₂ reflexivity.
Qed.

Context (Rf : PropEq1 f).
Context (RMonadFree_m : RMonadFree propeq1 propeq1).

Lemma RMonadFree_foldFree : RMonadFree Rf R.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
RMonadFree Rf R
Proof.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
RMonadFree Rf R
  constructor; intros.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
x₁: f a₁
x₂: f a₂
H2: Rf Ra x₁ x₂
R Ra (free x₁) (free x₂)
  -
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
x₁: f a₁
x₂: f a₂
H2: Rf Ra x₁ x₂
R Ra (free x₁) (free x₂) unfold R.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
x₁: f a₁
x₂: f a₂
H2: Rf Ra x₁ x₂
propeq1 Ra (foldFree (free x₁)) (free x₂)
    eapply trans_propeq1.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
x₁: f a₁
x₂: f a₂
H2: Rf Ra x₁ x₂
foldFree (free x₁) = ?x₁'
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
x₁: f a₁
x₂: f a₂
H2: Rf Ra x₁ x₂
propeq1 Ra ?x₁' ?x₂
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
x₁: f a₁
x₂: f a₂
H2: Rf Ra x₁ x₂
?x₂ = free x₂
    +
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
x₁: f a₁
x₂: f a₂
H2: Rf Ra x₁ x₂
foldFree (free x₁) = ?x₁' apply bind_pure.
    +
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
x₁: f a₁
x₂: f a₂
H2: Rf Ra x₁ x₂
propeq1 Ra (free x₁) ?x₂ apply RMonadFree_m.
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
x₁: f a₁
x₂: f a₂
H2: Rf Ra x₁ x₂
propeq1 Ra x₁ ?Goal0 eassumption.
    +
f, m: Type -> Type
H: Monad m
H0: MonadFree f m
H1: PropEq1 m
ReallyLawfulMonad0: ReallyLawfulMonad
R:= fun (a₁ a₂ : Type) 
  (Ra : a₁ -> a₂ -> Prop) 
  (u₁ : Free f a₁) 
  (u₂ : m a₂) => propeq1 Ra (foldFree u₁) u₂: forall a₁ a₂ : Type,
(a₁ -> a₂ -> Prop) -> Free f a₁ -> m a₂ -> Prop
Rf: PropEq1 f
RMonadFree_m: RMonadFree propeq1 propeq1
a₁, a₂: Type
Ra: a₁ -> a₂ -> Prop
x₁: f a₁
x₂: f a₂
H2: Rf Ra x₁ x₂
free x₂ = free x₂ reflexivity.
Qed.

End ISOPROOF.

Here comes the conclusion, which completes our claim that toFree'/fromFree' is an isomorphism (we proved the other half to_from on the way here). This equation is under an assumption which parametricity promises to fulfill, but we will have to step out of the system if we want it right now.

Theorem from_to f (Rf : PropEq1 f) a (u : Free' f a)
  : RFree' Rf eq u u ->
    toFree' (fromFree' u) = u.
f: Type -> Type
Rf: PropEq1 f
a: Type
u: Free' f a
RFree' Rf eq u u -> toFree' (fromFree' u) = u

In the proof, we get the assumption H : RFree' Rf eq u u, which we apply to the above lemmas, RMonad_foldFree and RMonadFree_foldFree, using the specialize tactic. That yields exactly our desired goal.

Proof.
f: Type -> Type
Rf: PropEq1 f
a: Type
u: Free' f a
RFree' Rf eq u u -> toFree' (fromFree' u) = u
  do 2 red; intros.
f: Type -> Type
Rf: PropEq1 f
a: Type
u: Free' f a
H: RFree' Rf eq u u
m: Type -> Type
H0: Monad m
H1: MonadFree f m
H2: PropEq1 m
ReallyLawfulMonadFree0: ReallyLawfulMonadFree
toFree' (fromFree' u) H1 = u m H0 H1
  unfold toFree', fromFree'.
f: Type -> Type
Rf: PropEq1 f
a: Type
u: Free' f a
H: RFree' Rf eq u u
m: Type -> Type
H0: Monad m
H1: MonadFree f m
H2: PropEq1 m
ReallyLawfulMonadFree0: ReallyLawfulMonadFree
foldFree (u (Free f) Monad_Free MonadFree_Free) =
u m H0 H1
  red in H.
f: Type -> Type
Rf: PropEq1 f
a: Type
u: Free' f a
H: forall (m₁ m₂ : Type -> Type) 
  (H : Monad m₁) 
  (H0 : MonadFree f m₁) 
  (H1 : Monad m₂) 
  (H2 : MonadFree f m₂)
  (Rm : forall a₁ a₂ : Type,
        (a₁ -> a₂ -> Prop) ->
        m₁ a₁ -> m₂ a₂ -> Prop),
RMonad Rm ->
RMonadFree Rf Rm ->
Rm a a eq (u m₁ H H0) (u m₂ H1 H2)
m: Type -> Type
H0: Monad m
H1: MonadFree f m
H2: PropEq1 m
ReallyLawfulMonadFree0: ReallyLawfulMonadFree
foldFree (u (Free f) Monad_Free MonadFree_Free) =
u m H0 H1
  specialize (H (Free f) m _ _ _ _ _ RMonad_foldFree (RMonadFree_foldFree RMonadFree_RLMF)).
f: Type -> Type
Rf: PropEq1 f
a: Type
u: Free' f a
m: Type -> Type
H0: Monad m
H1: MonadFree f m
H2: PropEq1 m
H: (fun (a₁ a₂ : Type) 
   (Ra : a₁ -> a₂ -> Prop) 
   (u₁ : Free f a₁) 
   (u₂ : m a₂) => 
 propeq1 Ra (foldFree u₁) u₂) a a eq
  (u (Free f) Monad_Free MonadFree_Free)
  (u m H0 H1)
ReallyLawfulMonadFree0: ReallyLawfulMonadFree
foldFree (u (Free f) Monad_Free MonadFree_Free) =
u m H0 H1
  apply H.
Qed.

Conclusion

If you managed to hang on so far, treat yourself to some chocolate.

To formalize a parametricity argument in Coq, I had to move the goalposts quite a bit throughout the experiment:

• Choose a more termination-friendly encoding of recursive types.
• Relativize equality.
• Mess around with heterogeneous relations without crashing into UIP.
• Reinvent the definition of a monad, again.
• Come to terms with the externality of parametricity.

It could be interesting to see a “really lawful monad” spelled out fully.

Another similar but simpler exercise is to prove the equivalence between initial and final encodings of lists. It probably wouldn’t involve “relation transformers” as much. There are also at least two different variants: is your final encoding “foldr”- or “fold”-based (the latter mentions monoids, the former doesn’t)?

I hope that machinery can be simplified eventually, but given the technical sophistication that is currently necessary, prudence is advised when navigating around claims made “by parametricity”.

---

Related reading

• Church encodings, inductive types, and relational parametricity, by Neel Krishnaswami

• Final algebra semantics is observational equivalence, by Max New

• Relational parametricity for higher kinds (PDF), by Robert Atkey

• Parametricity, type equality and higher-order polymorphism (PDF), by Dimitrios Vytiniotis and Stephanie Weirich

• Unary parametricity vs binary parametricity, on TCS StackExchange

• (F r -> r) -> r gives an initial algebra of F, on CS StackExchange

---

1. Answering Iceland_Jack’s question on Twitter.↩︎

2. Also an excuse to integrate Alectryon in my blog.↩︎

3. That idea is also present in Kiselyov and Ishii’s paper.↩︎

4. Those who do know Coq will wonder, what about eq (“intensional equality”)? It is a fine default relation for first-order data (nat, pairs, sums, lists, ASTs without HOAS). But it is too strong for computations (functions and coinductive types) and proofs (of Props). Then a common approach is to introduce extensionality axioms, postulating that “extensional equality implies intensional equality”. But you might as well just stop right after proving whatever extensional equality you wanted.↩︎

5. Well, if you tried you would end up with the unary variant of the parametricity theorem, but it’s much weaker than the binary version shown here. n-ary versions are also possible and even more general, but you have to look hard to find legitimate uses.↩︎

6. To be honest, that decision was a little arbitrary. But I’m not sure making things more complicated by keeping EqProp1 and EqProp separate buys us very much.↩︎

by Lysxia at October 20, 2021 12:00 AM