User-defined literals in Haskell via QuasiQuotes

A couple of days ago, somebody submitted a blog post to the Haskell subreddit, titled Abusing -XOverloadedStrings to Implement Type Directed Parsing.

I’m not totally sold on the ‘type-directed’ aspect (in fact, I’m generally quite reluctant to use type classes for this sort of thing, but that’s a topic for another day). Also, unfortunately, it turns out that the mechanism described in the above post can result in errors at runtime. However, I certainly agree that some mechanism for embedding literal values for arbitrary user-defined types ought to be a good thing, so I decided to investigate a little more.

Someone else also pointed out the very impressive refined library: https://nikita-volkov.github.io/refined/. However, I found it was just a little awkward to use for this particular use case, which is perhaps not surprising given that it appears to be designed for a slightly different one.

Having used Yesod’s quasiquoters for HTML templates, and knowing that most errors you can make in them get reported at compile time, it seemed to me like QuasiQuotes would be an appropriate thing to build this on top of.

Here’s what I came up with:

{-# LANGUAGE TemplateHaskell #-} {-# LANGUAGE RecordWildCards #-} module QQLiterals where import Language.Haskell.TH ( varE , Name ) import Language.Haskell.TH.Quote ( QuasiQuoter ( .. )) qqLiteral :: ( String -> Either String a ) -> Name -> QuasiQuoter qqLiteral parse parseFn = QuasiQuoter { .. } where quoteExp str = case parse str of Right _ -> [ | case $ ( varE parseFn ) str of { Right x -> x } | ] Left err -> fail err quotePat = unsupported "pattern" quoteType = unsupported "type" quoteDec = unsupported "declaration" unsupported context = fail $ "Unsupported operation: this QuasiQuoter can not be used in a " ++ context ++ " context."

To create a QuasiQuoter , you need to supply four functions: quoteExp , quotePat , quoteType , and quoteDec . We only care about quoting expressions here, so we use calls to fail in the others to ensure that they all fail immediately if our quasiquoter is used in an unsupported context.

The qqLiteral function takes two arguments. The first is a function which parses values of the type we’re interested in, which should return a Right value in case of success, or a Left value with an error message in case of failure. The second is a Name , which must refer to the same function passed as the first argument.

Whenever the resulting quasiquoter is used, our quoteExp function will be applied, at compile time, to the string inside the quoter. The resulting Q Exp value is then spliced back into the code.

So, our quoteExp function attempts to parse the string once at compile-time, using the function argument. If that is successful, it chucks away the result, since it’s not possible in general to turn this value back into an expression directly. Instead, it splices in an expression which should evaluate to the same thing, by applying the parser to the same string (as a string literal expression), and then performing an incomplete pattern match, matching only on the Right constructor. This ought to be safe, because we already checked the result is a Right value. If parsing is not successful, it calls fail which causes a compile-time error.

Here’s an example, using the URI type from network-uri :

{-# LANGUAGE TemplateHaskell #-} module Spec.Example where import Network.URI ( URI , parseURI ) import Language.Haskell.TH.Quote ( QuasiQuoter ) import QQLiterals ( qqLiteral ) eitherParseURI :: String -> Either String URI eitherParseURI str = maybe ( Left ( "Failed to parse URI: " ++ str )) Right ( parseURI str ) uri :: QuasiQuoter uri = qqLiteral eitherParseURI 'e i therParseURI

Here, in order to provide the Name argument, we quote the eitherParseURI function by prefixing it with a single-quote character.

Now, we can use the uri quasiquoter as follows:

{-# LANGUAGE QuasiQuotes #-} import Spec.Example ( uri ) import Network.URI ( URI ( .. )) main :: IO () main = do let exampleDotCom = [ uri | http://example.com/lol |] putStrLn ( "scheme: " ++ uriScheme exampleDotCom ) putStrLn ( "authority: " ++ show ( uriAuthority exampleDotCom )) putStrLn ( "path: " ++ uriPath exampleDotCom )

which produces the following output:

scheme: http: authority: Just (URIAuth {uriUserInfo = "", uriRegName = "example.com", uriPort = ""}) path: /lol

Using it with an invalid URI will fail at compile time; replacing the quasiquoted URI in the above program with [uri|invalid|] yields:

$ stack build <snip> [2 of 2] Compiling Main ( test/Spec.hs, .stack-work/dist/x86_64-osx/Cabal-1.22.5.0/build/qq-literals-test/qq-literals-test-tmp/Main.o ) /Users/hgarrood/Documents/code/qq-literals/test/Spec.hs:8:28: Failed to parse URI: invalid

I’m quite pleased with how this experiment turned out. I especially like that it (mostly) insulates users from the perils of Template Haskell. Of course, as a consumer of this, you yourself have to ensure that the Name argument does in fact refer to the same function, which is not ideal (and I would love to hear if there’s a better way of doing this). I might release this on Hackage if people think it’s a good enough idea. I’ve put the whole thing up on GitHub: https://github.com/hdgarrood/qq-literals/.

Thanks to everyone who participated in the original thread, without which this definitely wouldn’t have occurred to me.

This is now on Hackage: https://hackage.haskell.org/package/qq-literals/.