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I've noticed while on my quest to lean functional programming that there are cases when parameter lists start to become excessive when using nested immutable data structures. This is because when making an update to an object state, you need to update all the parent nodes in the data structure as well. Note that here I take "update" to mean "return a new immutable object with the appropriate change".

e.g. the kind of function I have found myself writing (Clojure example) is:

(defn update-object-in-world [world country city building object property value]
  (update-country-in-world world
    (update-city-in-country country
      (update-building-in-city building
        (update-object-in-building object property value))))) 

All this to update one simple property is pretty ugly, but in addition the caller has to assemble all the parameters!

This must be a fairly common requirement when dealing with immutable data structures in functional languages generally, so is there a good pattern or trick to avoid this that I should be using instead?

share|improve this question
You could flatten your data: store the worlds, countries, cities etc. separately. Then if you have to update one, update it in the flat structure. Link the data together via keys so you can put it together later when you need to. We're kind of re-inventing relational databases at this point though. – Brian Carper Jun 29 '10 at 16:59
up vote 2 down vote accepted

There are two approaches that I know of:

Collect multiple parameters in some sort of object that is convenient to pass around. Example:

; world is a nested hash, the rest are keys
(defstruct location :world :country :city :building)
(defstruct attribute :object :property)

(defn do-update[location attribute value]
  (let [{:keys [world country city building]} location
        {:keys [object property]} attribute ]
    (update-in world [country city building object property] value)))

This brings you down to two parameters that the caller needs to care about (location and attribute), which may be fair enough if those parameters do not change very often.

The other alternative is a with-X macro, which sets variables for use by the code body:

(defmacro with-location [location & body] ; run body in location context
    (list 'let ['{:keys [world country city building] :as location} `~location])

Example use:
(with-location location (println city))

Then whatever the body does, it does to the world/country/city/building set for it, and it can pass the entire thing off to another function using the "pre-assembled" location parameter.

Update: Now with a with-location macro that actually works.

share|improve this answer
Very useful, thanks! So it appears that even if you can't completely escape the proliferation of parameters, you can at least use macros or HoFs to make it look much nicer..... – mikera Jun 29 '10 at 15:37
Yes, wrapping them up in a convenient form is pretty much the best you can do. Sort of the way you do in object-oriented languages with "configuration objects" which exists only to encapsulate parameters. – j-g-faustus Jun 29 '10 at 15:48


  [country city building] 
  (update-object-in-building object property value))
share|improve this answer
Thanks - that's a very useful function that I hadn't seen before! However it still leaves us with a lot of parameters.... guess there is no way around that – mikera Jun 29 '10 at 13:06
look at assoc-in too – nickik Jun 29 '10 at 14:46

A classic general-purpose solution to this problem is what's called a "zipper" data structure. There are a number of variations, but the basic idea is simple: Given a nested data structure, take it apart as you traverse it, so that at each step you have a "current" element and a list of fragments representing how to reconstruct the rest of the data structure "above" the current element. A zipper can perhaps be thought of as a "cursor" that can move through an immutable data structure, replacing pieces as it goes, recreating only the parts it has to.

In the trivial case of a list, the fragments are just the previous elements of the list, stored in reverse order, and traversal is just moving the first element of one list to the other.

In the nontrivial but still simple case of a binary tree, the fragments each consist of a value and a subtree, identified as either right or left. Moving the zipper "down-left" involves adding to the fragment list the current element's value and right child, making the left child the new current element. Moving "down-right" works similarly, and moving "up" is done by combining the current element with the first value and subtree on the fragment list.

While the basic idea of the zipper is very general, constructing a zipper for a specific data structure usually requires some specialized bits, such as custom traversal or construction operations, to be used by a generic zipper implementation.

The original paper describing zippers (warning, PDF) gives example code in OCaml for an implementation storing fragments with an explicit path through a tree. Unsurprisingly, plenty of material can also be found on zippers in Haskell. As an alternative to constructing an explicit path and fragment list, zippers can be implemented in Scheme using continuations. And finally, there seems to even be a tree-oriented zipper provided by Clojure.

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