13

How does Haskell solve the "normalized immutable data structure" problem?

For example, let's consider a data structure representing ex girlfriends/boyfriends:

data Man = Man {name ::String, exes::[Woman]}

data Woman = Woman {name :: String, exes::[Man]}

What happens if a Woman changes her name and she had been with 13 man? Then all the 13 man should be "updated" (in the Haskell sense) too? Some kind of normalization is needed to avoid these "updates".

This is a very simple example, but imagine a model with 20 entities, and arbitrary relationships between them, what to do then?

What is the recommended way to represent complex, normalized data in an immutable language?

For example, a Scala solution can be found here (see code below), and it uses references. What to do in Haskell?

class RefTo[V](val target: ModelRO[V], val updated: V => AnyRef) {
  def apply() = target()
}

I wonder, if more general solutions like the one above (in Scala) don't work in Haskell or they are not necessary? If they don't work, then why not? I tried to search for libraries that do this in Haskell but they don't seem to exist.

In other words, if I want to model a normalized SQL database in Haskell (for example to be used with acid-state) is there a general way to describe foreign keys? By general I mean, not hand coding the IDs as suggested by chepner in the comments below.

EDIT:

Yet in other words, is there a library (for Haskell or Scala) that implements an SQL/relational database in memory (possibly also using Event Sourcing for persistence) such that the database is immutable and most of the SQL operations (query/join/insert/delete/etc.) are implemented and are type-safe ? If there is not such a library, why not ? It seems to be a pretty good idea. How should I create such a library ?

EDIT 2:

Some related links:

  • 6
    If you had normalized data, wouldn't you have data Man = Man {name :: String, exes :: [WomanID]}, where womanID was an index into a data structure story Woman values (something like Map WomanID Woman? If you change the name of a Woman value, this doesn't affect any Man value referencing it; you need only update the single value in the Map. – chepner Dec 17 '16 at 17:27
  • 2
    @jhegedus The question as it stands is a bit broad - it really depends on the situation. If you are constantly updating the the men and women, you may want to perform the computation in a state monad (the state being the table/map of men/women). If you are looking for a functional approach to more general graph structures, check out fgl. With respect to IDs: there are some situations where you can tie the knot (sometimes even using the Map), but in general you may need to hand code IDs. – Alec Dec 17 '16 at 18:21
  • 2
    A table represents a(n application) relationship; a FK represents the fact that if a certain subtuple is in one relationship then it's in another. What does a "way to represent complex, normalized data in an immutable language" have to do with "a general way to describe foreign keys"? Also, why "immutable"? It would seem to be a red herring, since (as acknowledged but not explained by your quoting "update") the issue is not about state per se (indeed the issue of update anomalies can really only arise under mutable semantics) but about a certain minimizing of invalid data structure values. – philipxy Dec 17 '16 at 20:34
  • 3
    I think this is an excellent question and I'm sorry to see all the close votes. I think you would find this blog post series (on "Purely Functional Retrogames") illuminating: prog21.dadgum.com/23.html – Seth Tisue Dec 18 '16 at 1:51
  • 1
    It's not immutability that is your difficulty. It's lack of an operator giving a value that looks like another value with a new part replacing an old part. Eg for a record type, there is such an operator for a part that is a field, and ' "update" ' is simple. Eg for a table of rows, many rows may change. Regardless of mutability. We walk a representation to update parts. Under immutability having to clone but under mutability possibly cloning. "Normalization" is in a general sense restructuring to reduce that walking and the number of parts. Mutability vs immutability is not at issue. – philipxy Dec 18 '16 at 21:24
9

The problem is you are storing data and relationships in the same type. To normalise, you need to separate. Relational databases 101.

newtype Id a = Id Int -- Type-safe ID.
data Person = Person { id :: Id Person, name :: String }
data Ex = Ex { personId :: Id Person, exId :: Id Person }

Now if a person changes their name, only a single Person value is affected. The Ex entries don't care about peoples' names.

| improve this answer | |
  • 1
    Interesting point! It's a many to many relationship, indeed. What I was after however - as mentioned in the question as well - is "not hand coding the IDs as suggested by chepner in the comments below." Some kind of a library that does what you suggested but takes away all the boilerplate and adds support for queries, joins and whatnot. Basically an SQL database but instead of using SQL as a query language it uses Haskell to describe things that can be described with SQL. Type safe and immutable. – jhegedus Feb 20 '17 at 9:40
  • @jhegedus here's the thing. You can't abstract away the foreign key; it's part of your domain semantics--i.e., it answers the question 'What makes a person in the relationship uniquely that person?' No library can decide that for you. – Yawar Feb 20 '17 at 16:40
  • So basically Ex corresponds to an SQL database table which needs to be explicitly specified. I get that but maybe SQL can be replaced by Haskell, fully type safe, immutable. Or not ? I wonder why that has not been done ? (Not a binding to a database, but an actual in-memory database, written in Haskell). I am asking this because a friend is writing a (successful) app in Scala, and is doing exactly that because 1) no duplication of data (memory-database), 2) type safety 3) Scala is more expressive than SQL. So if it is worth to do that in Scala, why no Haskell lib. exists for that ? I wonder – jhegedus Feb 20 '17 at 20:18
  • @jhegedus not sure, I'm not being able to verify what the Scala code is doing--the link in your question is 404ing. – Yawar Feb 21 '17 at 13:32
  • 1
    @jhegedus three things. (1) the RefTo type is still under the hood using some identifier as the base reference. Notice that you have to manually tell it how to get a product uniquely by ID. (2) I'm not convinced of the additional value brought by the Diode approach. Feels like I could have immutability with FRP (/streaming). (3) Haskell people probably haven't acutely felt the need for a wrapper over identifier references, because of lenses and language-level niceties. It may be simpler to just do it manually. – Yawar Feb 23 '17 at 0:25
0
+100

Project M63 comes pretty close to what I was looking for. It is written in Haskell.

A more lightweight Haskell solution is outlined in Gabriel Gonzalez's post "A very general API for relational joins".

| improve this answer | |
  • Can you provide an example of how you would apply Project M63 specifically to the model you asked about? Also, the link with text 'close' seems to be to a message in your personal Gmail inbox. Gabriel Gonzalez' join technique is pretty damn cool though--but it still doesn't abstract away ID management 😉 – Yawar Feb 27 '17 at 18:12
  • Thanks, I fixed the link. – jhegedus Feb 27 '17 at 20:40
  • I don't know how to use M36, based on the description however it seems to be what I was looking for. Immutable relational database. It seems at the moment that there is no Scala equivalent (at least not a public one). Or maybe I just don't know about it ? It would be interesting to know if there is something like M36 for Scala. – jhegedus Feb 27 '17 at 20:49

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.