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I find it very common to want to model relational data in my functional programs. For example, when developing a web-site I may want to have the following data structure to store info about my users:

data User = User 
  { name :: String
  , birthDate :: Date
  }

Next, I want to store data about the messages users post on my site:

data Message = Message
  { user :: User
  , timestamp :: Date
  , content :: String
  }

There are multiple problems associated with this data structure:

  • We don't have any way of distinguishing users with similar names and birth dates.
  • The user data will be duplicated on serialisation/deserialisation
  • Comparing the users requires comparing their data which may be a costly operation.
  • Updates to the fields of User are fragile -- you can forget to update all the occurences of User in your data structure.

These problems are manageble while our data can be represented as a tree. For example, you can refactor like this:

data User = User
  { name :: String
  , birthDate :: Date
  , messages :: [(String, Date)] -- you get the idea
  }

However, it is possible to have your data shaped as a DAG (imagine any many-to-many relation), or even as a general graph (OK, maybe not). In this case, I tend to simulate the relational database by storing my data in Maps:

newtype Id a = Id Integer
type Table a = Map (Id a) a

This kind of works, but is unsafe and ugly for multiple reasons:

  • You are just an Id constructor call away from nonsensical lookups.
  • On lookup you get Maybe a, but often the database structurally ensures that there is a value.
  • It is clumsy.
  • It is hard to ensure referential integrity of your data.
  • Managing indices (which are very much necessary for performance) and ensuring their integrity is even harder and clumsier.

Is there existing work on overcoming these problems?

It looks like Template Haskell could solve them (as it usually does), but I would like not to reinvent the wheel.

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4 Answers

The ixset library will help you with this. It's the library that backs the relational part of acid-state, which also handles versioned serialization of your data and/or concurrency guarantees, in case you need it.

The thing about ixset is that it manages "keys" for your data entries automatically.

For your example, one would create one-to-many relationships for your data types like this:

data User =
  User
  { name :: String
  , birthDate :: Date
  } deriving (Ord, Typeable)

data Message =
  Message
  { user :: User
  , timestamp :: Date
  , content :: String
  } deriving (Ord, Typeable)

instance Indexable Message where
  empty = ixSet [ ixGen (Proxy :: Proxy User) ]

You can then find the message of a particular user. If you have built up an IxSet like this:

user1 = User "John Doe" undefined
user2 = User "John Smith" undefined

messageSet =
  foldr insert empty
  [ Message user1 undefined "bla"
  , Message user2 undefined "blu"
  ]

... you can then find messages by user1 with:

user1Messages = toList $ messageSet @= user1

If you need to find the user of a message, just use the user function like normal. This models a one-to-many relationship.

Now, for many-to-many relations, with a situation like this:

data User =
  User
  { name :: String
  , birthDate :: Date
  , messages :: [Message]
  } deriving (Ord, Typeable)

data Message =
  Message
  { users :: [User]
  , timestamp :: Date
  , content :: String
  } deriving (Ord, Typeable)

... you create an index with ixFun, which can be used with lists of indexes. Like so:

instance Indexable Message where
  empty = ixSet [ ixFun users ]

instance Indexable User where
  empty = ixSet [ ixFun messages ]

To find all the messages by an user, you still use the same function:

user1Messages = toList $ messageSet @= user1

Additionally, provided that you have an index of users:

userSet =
  foldr insert empty
  [ User "John Doe" undefined [ messageFoo, messageBar ]
  , User "John Smith" undefined [ messageBar ]
  ]

... you can find all the users for a message:

messageFooUsers = toList $ userSet @= messageFoo

If you don't want to have to update the users of a message or the messages of a user when adding a new user/message, you should instead create an intermediary data type that models the relation between users and messages, just like in SQL (and remove the users and messages fields):

data UserMessage = UserMessage { umUser :: User, umMessage :: Message } 

instance Indexable UserMessage where
  empty = ixSet [ ixGen (Proxy :: Proxy User), ixGen (Proxy :: Proxy Message) ]

Creating a set of these relations would then let you query for users by messages and messages for users without having to update anything.

The library has a very simple interface considering what it does!

EDIT: Regarding your "costly data that needs to be compared": ixset only compares the fields that you specify in your index (so to find all the messages by a user in the first example, it compares "the whole user").

You regulate which parts of the indexed field it compares by altering the Ord instance. So, if comparing users is costly for you, you can add an userId field and modify the instance Ord User to only compare this field, for example.

This can also be used to solve the chicken-and-egg problem: what if you have an id, but neither a User, nor a Message?

You could then simply create an explicit index for the id, find the user by that id (with userSet @= (12423 :: Id)) and then do the search.

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Doesn't the one-to-many model shown here share all the disadvantages of the original model from the question? –  ehird Feb 10 '12 at 21:11
    
@ehird, I make about 10 edits per minute, so I think that I've answered your concern along the way. –  dflemstr Feb 10 '12 at 21:37
    
Yes, indeed. (BTW, acid-state doesn't actually depend on ixset; they're just designed to be used together.) –  ehird Feb 10 '12 at 22:03
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I don't have a complete solution, but I suggest taking a look at the ixset package; it provides a set type with an arbitrary number of indices that lookups can be performed with. (It's intended to be used with acid-state for persistence.)

You do still need to manually maintain a "primary key" for each table, but you could make it significantly easier in a few ways:

  1. Adding a type parameter to Id, so that, for instance, a User contains an Id User rather than just an Id. This ensures you don't mix up Ids for separate types.

  2. Making the Id type abstract, and offering a safe interface to generating new ones in some context (like a State monad that keeps track of the relevant IxSet and the current highest Id).

  3. Writing wrapper functions that let you, for example, supply a User where an Id User is expected in queries, and that enforce invariants (for example, if every Message holds a key to a valid User, it could allow you to look up the corresponding User without handling a Maybe value; the "unsafety" is contained within this helper function).

As an additional note, you don't actually need a tree structure for regular data types to work, since they can represent arbitrary graphs; however, this makes simple operations like updating a user's name impossible.

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Another radically different approach to representing relational data is used by the database package haskelldb. It doesn't work quite like the types you describe in your example, but it is designed to allow a type-safe interface to SQL queries. It has tools for generating data types from a database schema and vice versa. Data types such as the ones you describe work well if you always want to work with whole rows. But they don't work in situations where you want to optimize your queries by only selecting certain columns. This is where the HaskellDB approach can be useful.

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IxSet is the ticket. To help others who might stumble on this post here's a more fully expressed example,

{-# LANGUAGE OverloadedStrings, DeriveDataTypeable, TypeFamilies, TemplateHaskell #-}

module Main (main) where

import Data.Int
import Data.Data
import Data.IxSet
import Data.Typeable

-- use newtype for everything on which you want to query; 
-- IxSet only distinguishes indexes by type
data User = User 
  { userId :: UserId
  , userName :: UserName }
  deriving (Eq, Typeable, Show, Data)
newtype UserId = UserId Int64
  deriving (Eq, Ord, Typeable, Show, Data)
newtype UserName = UserName String
  deriving (Eq, Ord, Typeable, Show, Data)

-- define the indexes, each of a distinct type
instance Indexable User where
   empty = ixSet 
      [ ixFun $ \ u -> [userId u]
      , ixFun $ \ u -> [userName u]
      ]

-- this effectively defines userId as the PK
instance Ord User where
   compare p q = compare (userId p) (userId q)

-- make a user set
userSet :: IxSet User
userSet = foldr insert empty $ fmap (\ (i,n) -> User (UserId i) (UserName n)) $ 
    zip [1..] ["Bob", "Carol", "Ted", "Alice"]

main :: IO ()
main = do
  -- Here, it's obvious why IxSet needs distinct types.
  showMe "user 1" $ userSet @= (UserId 1)
  showMe "user Carol" $ userSet @= (UserName "Carol")
  showMe "users with ids > 2" $ userSet @> (UserId 2)
  where
  showMe :: (Show a, Ord a) => String -> IxSet a -> IO ()
  showMe msg items = do
    putStr $ "-- " ++ msg
    let xs =  toList items
    putStrLn $ " [" ++ (show $ length xs) ++ "]"
    sequence_ $ fmap (putStrLn . show) xs
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