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I'm trying to make a serialization/deserialization using read and show (which is not a problem per se), but extensible in a sense that the data type can be extended (but not shrunk).

Suppose I have this type:

data Foo = { bar :: Int } deriving (Show, Read)

And the list:

foos = [Foo 1, Foo 2]

I can easily deserialize it into a file:

hPutStrLn fileHand . ppShow $ foos

Then I can serialize it back:

!str <- hGetContents fileHand
let foosFromFile = fromMaybe [] $ (readMaybe :: String -> Maybe [Foo]) str

But suppose that months later I want to add a 'baz' field into the Foo type. The direct serialization from the old-format file will no longer work with read, I will need to convert the file (which I don't really want).

So, is there an elegant (without putting an explicit versioning logic in the program itself) solution to still serialize the data from a file, and filling-in missing fields with default values? Maybe some types tricks?

Thanks.

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4 Answers 4

This might not be what you are looking for since you want to avoid explicit versioning but I'd still like to point out safecopy which is the go-to solution for versioned serialization and at least makes it somewhat painless.

I don't think there's any way to use the default Show and Read instances while supporting adding an arbitrary amount of new fields, but you can of course write your own Read instance by hand which handles the missing record fields. However, I think that's more laborious and error prone than just using safecopy.

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I had never heard of SafeCopy. Nifty :-) –  luqui Aug 16 '13 at 6:51
    
+1 for safecopy. Will definitely use it. –  insitu Sep 26 at 9:01

Depending on your use case, you could also use persistent from Yesod to persist your data in a database. Quoting:

Persistent follows the guiding principles of type safety and concise, declarative syntax. Some other nice features are:

  • Database-agnostic. There is first class support for PostgreSQL, SQLite, MySQL and MongoDB, with experimental CouchDB support in the works.
  • By being non-relational in nature, we simultaneously are able to support a wider number of storage layers and are not constrained by some of the performance bottlenecks incurred through joins.
  • A major source of frustration in dealing with SQL databases is changes to the schema. Persistent can automatically perform database migrations.

Persistent handles changes in your data for you in those cases:

For the following cases, it will automatically alter the schema:

  • The datatype of a field changed. However, the database may object to this modification if the data cannot be translated.
  • A field was added. However, if the field is not null, no default value is supplied (we’ll discuss defaults later) and there is already data in the database, the database will not allow this to happen.
  • A field is converted from not null to null. In the opposite case, Persistent will attempt the conversion, contingent upon the database’s approval.
  • A brand new entity is added.
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Wanting to be able to change the data layout while still being able to access your stuff is pretty much one of the defining motivations for inventing database management systems. Have you considered just dropping your data into a simple SQLite table? It might be overkill for what you're trying to do, but it has some advantages:

  • Almost certainly more efficient than a text-based encoding.
  • You can still easily read it from outside your application (e.g., to check that the correct thing has been saved).
  • "Converting the file" now amounts to a simple SQL query.
  • If you avoid using * as a column selector, your old code can still read stuff created by newer versions of the application. (I.e., forwards compatibility as well as backwards).
  • Alternatively, you can read write some simple boilerplate code that reads the DB schema and supplies default values for any columns that don't exist yet.

I don't know if this is appropriate for your case, but it's worth thinking about.

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Yes. Just add a polymorphic field:

data Foo a = { bar :: Int, extra :: a } deriving (Show, Read)

Then define a serialization instance with the constraint that a must be serializable:

instance (Serialize a) => Serialize (Foo a) where ...

When you're not using the extra field, just insert a () into it, since () is trivially serializable (and already has a Serialize instance).

Edit: Oops, just realized you are talking about pretty printing. The equivalent solution is to define a type class like this:

class PrettyPrint a where
    pp :: a -> String

instance PrettyPrint () where
    pp () = ""

instance (PrettyPrint a) => PrettyPrint (Foo a) where
    pp = ... -- You fill this in
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