Recently, there has been some new discussion around the issue of providing default values for function parameters in Haskell. First, Gabriel Gonzalez showed us his new optional-args library, which provides new types for optional arguments along with heavy syntactic overloading. To follow that, Dimitri Sabadie published a blog post discouraging the use of the currently popular Default type class. These are both good discussions, and as with any good discussion have been lingering around in the back of my head.
Since those discussions took place, I’ve been playing with my point in the FRP-web-framework design space - Francium. I made some big refactorings on an application using Francium, mostly extending so called “component” data types (buttons, checkboxes, etc), and was frustrated with how much code broke just from introducing new record fields. The Commercial Haskell group published an article on how to design for extensibility back in March, so I decided to revisit that.
It turns out that with a little bit of modification, the approach proposed in designing for extensibility also covers optional arguments pretty well!
First, let’s recap what it means to design for extensibility. The key points are:
Settings values, which specify a general configuration.Settings values are opaque, meaning they cannot be constructed by a data constructor, but they have a smart constructor instead. This smart constructor allows you to provide default values.Settings data type, preventing the use of record syntax for updates (which leaks implementation details).Regular Haskell users will already be familiar a pattern that can be seen in point 3: we often use a different piece of technology to solve this problem - lenses. Lenses are nice here because they reduce the surface area of our API - two exports can be reduced to just one, which I believe reduces the time to learn a new library. They also compose very nicely, in that they can be embedded into other computations with ease.
With point 3 amended to use some form of lens, we end up with the following type of presentation. Take a HTTP library for example. Our hypothetical library would have the following exports:
data HTTPSettings
httpKeepAlive :: Lens HTTPSettings Bool
httpCookieJar :: Lens HTTPSettings CookieJar
defaultHTTPSettings :: HTTPSettings
httpRequest :: HTTPSettings -> HTTPRequest -> IO Responsewhich might have usage
httpRequest
(defaultHTTPSettings & httpKeepAlive .~ True)
aRequestThis is an improvement, but I’ve never particularly liked the reverse function application stuff with &. The repeated use of & is essentially working in an Endo Writer monad, or more generally - a state monad. The lens library ships with operators for working specifically in state monads (of course it does), so let’s use that:
httpRequest :: State HTTPSettings x -> HTTPRequest -> IO Response
....
httpRequest
(do httpKeepAlive .= True)
aRequestIt’s a small change here, but when you are overriding a lot of parameters, the sugar offered by the use of do is hard to give up - especially when you throw in more monadic combinators like when and unless.
With this seemingly simple syntactic change, something interesting has happened; something which is easier to see if we break open httpRequest:
httpRequest :: State HTTPSettings x -> HTTPRequest -> IO Response
httpRequest mkConfig request =
let config = execState mkConfig defaultHttpSettings
in ...Now the default configuration has moved inside the HTTP module, rather than being supplied by the user. All the user provides is essentially a function HTTPSettings -> HTTPSettings, dressed up in a state monad. This means that to use the default configuration, we simply provide a do-nothing state composition: return (). We can even give this a name
def :: State a ()
def = return ()and voila, we now have the lovely name-overloading offered by Data.Default, but without the need to introduce a lawless type class!
To conclude, in this post I’ve shown that by slightly modifying the presentation of an approach to build APIs with extensibility in mind, we the main benefit of Data.Default. This main benefit - the raison d’être of Data.Default - is the ability to use the single symbol def whenever you just want a configuration, but don’t care what it is. We still have that ability, and we didn’t have to rely on an ad hoc type class to get there.
However, it’s not all rainbows and puppies: we did have to give something up to get here, and what we’ve given up is a compiler enforced consistency. With Data.Default, there is only a single choice of default configuration for a given type, so you know that def :: HTTPSettings will be the same set of defaults everywhere. With my approach, exactly what def means is down to the function you’re calling and how they want to interpret def. In practice, due to the lack of laws on def, there wasn’t much reasoning you could do about what that single instance was anyway, so I’m not sure much is given up in practice. I try and keep to a single interpretation of def in my libraries by still exporting defaultHTTPSettings, and then using execState mkConfig defaultHTTPSettings whenever I need to interpret a State HTTPConfig.
You can contact me via email at ollie@ocharles.org.uk or tweet to me @acid2. I share almost all of my work at GitHub. This post is licensed under a Creative Commons Attribution-NonCommercial-NoDerivs 3.0 Unported License.
I accept Bitcoin donations: 14SsYeM3dmcUxj3cLz7JBQnhNdhg7dUiJn. Alternatively, please consider leaving a tip on