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# how to reify a list of data using Data.Reify?

I tried to read the paper (http://www.ittc.ku.edu/csdl/fpg/sites/default/files/Gill-09-TypeSafeReification.pdf) and managed to reify my symbolic expression type, but I can't figure out how to reify a list of them. Here's the simplified code:

``````{-# OPTIONS_GHC -Wall #-}
{-# Language TypeOperators #-}
{-# Language TypeFamilies #-}
{-# Language FlexibleInstances #-}

import Control.Applicative
import Data.Reify

-- symbolic expression type
data Expr a = EConst a
| EBin (Expr a) (Expr a)
deriving Show

-- corresponding node type
data GraphExpr a b = GConst a
| GBin b b
deriving Show

instance MuRef (Expr a) where
type DeRef (Expr a) = GraphExpr a
mapDeRef _ (EConst c)  = pure (GConst c)
mapDeRef f (EBin u v) = GBin <\$> f u <*> f v

-- this works as expected
main :: IO ()
main = reifyGraph (EBin x (EBin x y)) >>= print
where
x = EConst "x"
y = EConst "y"
-- (output: "let [(1,GBin 2 3),(3,GBin 2 4),(4,GConst "y"),(2,GConst "x")] in 1")

-- but what if I want to reify a list of Exprs?
data ExprList a = ExprList [Expr a]
data GraphList a b = GraphList [GraphExpr a b]

instance MuRef (ExprList a) where
type DeRef (ExprList a) = GraphList a
--  mapDeRef f (ExprList xs) = ???????
``````
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You really can't do that with MuRef. GraphLists don't contain GraphLists. You can reify each Expr in turn and write a one-off combinator to smash them into your GraphList though:

Just use traverse reifyGraph over the ExprList contents.

Also, both of the latter should probably be newtypes.

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I don't know what you mean by one-off combinator. Does this mean that if I have a common intermediate node that appears in two outputs, my only option is to perform reifyGraph on both outputs and then do explicit CSE with a hashmap or something? Is this a limitation of reifyGraph or StablePtr? – ghorn Jul 27 '12 at 23:28
Well, reifyGraph is only designed to deal with monomorphic recursion. Here you need to recurse polymorphically into the expressions. There isn't anything really stopping the creation of a combinator in data-reify that provides this sort of service, but there isn't one there now. – Edward KMETT Jul 28 '12 at 1:36

I had the exact same problem, and I found a solution using data-reify.

The things you have to realise to arrive at a solution is that: 1. Even though the EDSL doesnt have lists, the graph type could contain them 2. It is possible to reify different types of data to the same result type.

So we start by adding list constructors to our result type:

``````data GraphExpr a b = GConst a
| GBin b b
| Cons b b
| Nil
deriving Show
``````

Then we need a second instance of MuRef, that reifies lists of Expr a to GraphExpr.

``````instance MuRef [Expr a] where
type DeRef [Expr a] = GraphExpr a
mapDeRef _ [] = pure Nil
mapDeRef f (x:xs) = Cons <\$> f x <*> f xs
``````

Now with this in place, if we try to reify a list expression

``````reified = reifyGraph [EBin x (EBin x y), Ebin y (EBin x y)]
where x = EConst "x"
y = EConst "y"
``````

We'll get the result

``````let [(1,Cons 2 6),(6,Cons 7 9),(9,Nil),(7,GBin 5 8),(8,GBin 3 5),(2,GBin 3 4),(4,GBin 3 5),(5,GConst "y"),(3,GConst "x")] in 1
``````

To extract the list of reified node-ids from this graph we can define a little function to walk the Conses and to extract the node-ids from them into a list.

``````walkConses :: Graph (GraphExpr t) -> [Unique]
walkConses (Graph xs root) = go (lookup root xs)
where
go (Just (Cons n1 n2)) = n1 : go (lookup n2 xs)
go (Just Nil) = []
``````

(If the graphs are huge, it might be a good idea to convert them to an IntMap before starting the walk)

This looks like a partial function, but since we know that the root of the DAG will always be a Cons-node (since we reify a list), and since we know that all node-ids are in xs this function will return a list of all node-ids in the result list.

So if we run walkConses on our resulting graph we'll get the result:

``````[2, 7]
``````

Hope this helps, I've been wrestling with this problem for a while too.

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