I am trying to implement a huge Java interface with numerous (~50) getter and setter methods (some with irregular names). I thought it would be nice to use a macro to reduce the amount of code. So instead of
(def data (atom {:x nil}))
(reify HugeInterface
(getX [this] (:x @data))
(setX [this v] (swap! data assoc :x v)))
I want to be able to write
(def data (atom {:x nil}))
(reify HugeInter开发者_运维知识库face
(set-and-get getX setX :x))
Is this set-and-get macro (or something similar) possible? I haven't been able to make it work.
(Updated with a second approach -- see below the second horizontal rule -- as well as some explanatory remarks re: the first one.)
I wonder if this might be a step in the right direction:
(defmacro reify-from-maps [iface implicits-map emit-map & ms]
`(reify ~iface
~@(apply concat
(for [[mname & args :as m] ms]
(if-let [emit ((keyword mname) emit-map)]
(apply emit implicits-map args)
[m])))))
(def emit-atom-g&ss
{:set-and-get (fn [implicits-map gname sname k]
[`(~gname [~'this] (~k @~(:atom-name implicits-map)))
`(~sname [~'this ~'v]
(swap! ~(:atom-name implicits-map) assoc ~k ~'v))])})
(defmacro atom-bean [iface a & ms]
`(reify-from-maps ~iface {:atom-name ~a} ~emit-atom-g&ss ~@ms))
NB. that the atom-bean
macro passes the actual compile-time value of emit-atom-g&ss
on to reify-from-maps
. Once a particular atom-bean
form is compiled, any subsequent changes to emit-atom-g&ss
have no effect on the behaviour of the created object.
An example macroexpansion from the REPL (with some line breaks and indentation added for clarity):
user> (-> '(atom-bean HugeInterface data
(set-and-get setX getX :x))
macroexpand-1
macroexpand-1)
(clojure.core/reify HugeInterface
(setX [this] (:x (clojure.core/deref data)))
(getX [this v] (clojure.core/swap! data clojure.core/assoc :x v)))
Two macroexpand-1
s are necessary, because atom-bean
is a macro which expands to a further macro call. macroexpand
would not be particularly useful, as it would expand this all the way to a call to reify*
, the implementation detail behind reify
.
The idea here is that you can supply an emit-map
like emit-atom-g&ss
above, keyed by keywords whose names (in symbolic form) will trigger magic method generation in reify-from-maps
calls. The magic is performed by the functions stored as functions in the given emit-map
; the arguments to the functions are a map of "implicits" (basically any and all information which should be accessible to all method definitions in a reify-from-maps
form, like the name of the atom in this particular case) followed by whichever arguments were given to the "magic method specifier" in the reify-from-maps
form. As mentioned above, reify-from-maps
needs to see an actual keyword -> function map, not its symbolic name; so, it's only really usable with literal maps, inside other macros or with help of eval
.
Normal method definitions can still be included and will be treated as in a regular reify
form, provided keys matching their names do not occur in the emit-map
. The emit functions must return seqables (e.g. vectors) of method definitions in the format expected by reify
: in this way, the case with multiple method definitions returned for one "magic method specifier" is relatively simple. If the iface
argument were replaced with ifaces
and ~iface
with ~@ifaces
in reify-from-maps
' body, multiple interfaces could be specified for implementation.
Here's another approach, possibly easier to reason about:
(defn compile-atom-bean-converter [ifaces get-set-map]
(eval
(let [asym (gensym)]
`(fn [~asym]
(reify ~@ifaces
~@(apply concat
(for [[k [g s]] get-set-map]
[`(~g [~'this] (~k @~asym))
`(~s [~'this ~'v]
(swap! ~asym assoc ~k ~'v))])))))))
This calls on the compiler at runtime, which is somewhat expensive, but only needs to be done once per set of interfaces to be implemented. The result is a function which takes an atom as an argument and reifies a wrapper around the atom implementing the given interfaces with getters and setters as specified in the get-set-map
argument. (Written this way, this is less flexible than the previous approach, but most of the code above could be reused here.)
Here's a sample interface and a getter/setter map:
(definterface IFunky
(getFoo [])
(^void setFoo [v])
(getFunkyBar [])
(^void setWeirdBar [v]))
(def gsm
'{:foo [getFoo setFoo]
:bar [getFunkyBar setWeirdBar]})
And some REPL interactions:
user> (def data {:foo 1 :bar 2})
#'user/data
user> (def atom-bean-converter (compile-atom-bean-converter '[IFunky] gsm))
#'user/atom-bean-converter
user> (def atom-bean (atom-bean-converter data))
#'user/atom-bean
user> (.setFoo data-bean 3)
nil
user> (.getFoo atom-bean)
3
user> (.getFunkyBar data-bean)
2
user> (.setWeirdBar data-bean 5)
nil
user> (.getFunkyBar data-bean)
5
The point is reify being a macro itself which is expanded before your own set-and-get macro - so the set-and-get approach doesn't work. So, instead of an inner macro inside reify, you need a macro on the "outside" that generates the reify, too.
Since the trick is to expand the body before reify sees it, a more general solution could be something along these lines:
(defmacro reify+ [& body]
`(reify ~@(map macroexpand-1 body)))
You can also try to force your macro to expand first:
(ns qqq (:use clojure.walk))
(defmacro expand-first [the-set & code] `(do ~@(prewalk #(if (and (list? %) (contains? the-set (first %))) (macroexpand-all %) %) code)))
(defmacro setter [setterf kw] `(~setterf [~'this ~'v] (swap! ~'data assoc ~kw ~'v)))
(defmacro getter [getterf kw] `(~getterf [~'this] (~kw @~'data)))
(expand-first #{setter getter}
(reify HugeInterface
(getter getX :x)
(setter setX :x)))
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