dfa4c4847c
Change-Id: Ia27be70ef07d9aa7d13821a2808ded9cf16506c8 Reviewed-on: https://cl.tvl.fyi/c/depot/+/7073 Reviewed-by: sterni <sternenseemann@systemli.org> Autosubmit: sterni <sternenseemann@systemli.org> Tested-by: BuildkiteCI
255 lines
7.3 KiB
Nix
255 lines
7.3 KiB
Nix
{ depot, lib, ... }:
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let
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inherit (lib)
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id
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;
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# Simple function composition,
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# application is right to left.
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rl = f1: f2:
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(x: f1 (f2 x));
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# Compose a list of functions,
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# application is right to left.
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rls = fs:
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builtins.foldl' (fOut: f: lr f fOut) id fs;
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# Simple function composition,
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# application is left to right.
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lr = f1: f2:
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(x: f2 (f1 x));
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# Compose a list of functions,
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# application is left to right
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lrs = x: fs:
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builtins.foldl' (v: f: f v) x fs;
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# Warning: cursed function
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#
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# Check if a function has an attribute
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# set pattern with an ellipsis as its argument.
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#
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# s/o to puck for discovering that you could use
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# builtins.toXML to introspect functions more than
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# you should be able to in Nix.
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hasEllipsis = f:
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builtins.isFunction f &&
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builtins.match ".*<attrspat ellipsis=\"1\">.*"
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(builtins.toXML f) != null;
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/* Return the number of arguments the given function accepts or 0 if the value
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is not a function.
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Example:
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argCount argCount
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=> 1
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argCount builtins.add
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=> 2
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argCount pkgs.stdenv.mkDerivation
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=> 1
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*/
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argCount = f:
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let
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# N.B. since we are only interested if the result of calling is a function
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# as opposed to a normal value or evaluation failure, we never need to
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# check success, as value will be false (i.e. not a function) in the
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# failure case.
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called = builtins.tryEval (
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f (builtins.throw "You should never see this error message")
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);
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in
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if !(builtins.isFunction f || builtins.isFunction (f.__functor or null))
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then 0
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else 1 + argCount called.value;
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/* Call a given function with a given list of arguments.
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Example:
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apply builtins.sub [ 20 10 ]
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=> 10
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*/
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apply = f: args:
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builtins.foldl' (f: x: f x) f args;
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# TODO(sterni): think of a better name for unapply
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/* Collect n arguments into a list and pass them to the given function.
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Allows calling a function that expects a list by feeding it the list
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elements individually as function arguments - the limitation is
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that the list must be of constant length.
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This is mainly useful for functions that wrap other, arbitrary functions
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in conjunction with argCount and apply, since lists of arguments are
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easier to deal with usually.
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Example:
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(unapply 3 lib.id) 1 2 3
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=> [ 1 2 3 ]
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(unapply 5 lib.reverse) 1 2 null 4 5
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=> [ 5 4 null 2 1 ]
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# unapply and apply compose the identity relation together
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unapply (argCount f) (apply f)
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# is equivalent to f (if the function has a constant number of arguments)
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(unapply 2 (apply builtins.sub)) 20 10
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=> 10
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*/
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unapply =
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let
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unapply' = acc: n: f: x:
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if n == 1
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then f (acc ++ [ x ])
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else unapply' (acc ++ [ x ]) (n - 1) f;
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in
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unapply' [ ];
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/* Optimize a tail recursive Nix function by intercepting the recursive
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function application and expressing it in terms of builtins.genericClosure
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instead. The main benefit of this optimization is that even a naively
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written recursive algorithm won't overflow the stack.
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For this to work the following things prerequisites are necessary:
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- The passed function needs to be a fix point for its self reference,
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i. e. the argument to tailCallOpt needs to be of the form
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`self: # function body that uses self to call itself`.
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This is because tailCallOpt needs to manipulate the call to self
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which otherwise wouldn't be possible due to Nix's lexical scoping.
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- The passed function may only call itself as a tail call, all other
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forms of recursions will fail evaluation.
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This function was mainly written to prove that builtins.genericClosure
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can be used to express any (tail) recursive algorithm. It can be used
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to avoid stack overflows for deeply recursive, but naively written
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functions (in the context of Nix this mainly means using recursion
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instead of (ab)using more performant and less limited builtins).
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A better alternative to using this function is probably translating
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the algorithm to builtins.genericClosure manually. Also note that
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using tailCallOpt doesn't mean that the stack won't ever overflow:
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Data structures, especially lazy ones, can still cause all the
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available stack space to be consumed.
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The optimization also only concerns avoiding stack overflows,
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tailCallOpt will make functions slower if anything.
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Type: (F -> F) -> F where F is any tail recursive function.
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Example:
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let
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label' = self: acc: n:
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if n == 0
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then "This is " + acc + "cursed."
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else self (acc + "very ") (n - 1);
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# Equivalent to a naive recursive implementation in Nix
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label = (lib.fix label') "";
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labelOpt = (tailCallOpt label') "";
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in
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label 5
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=> "This is very very very very very cursed."
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labelOpt 5
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=> "This is very very very very very cursed."
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label 10000
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=> error: stack overflow (possible infinite recursion)
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labelOpt 10000
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=> "This is very very very very very very very very very…
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*/
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tailCallOpt = f:
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let
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argc = argCount (lib.fix f);
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# This function simulates being f for f's self reference. Instead of
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# recursing, it will just return the arguments received as a specially
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# tagged set, so the recursion step can be performed later.
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fakef = unapply argc (args: {
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__tailCall = true;
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inherit args;
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});
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# Pass fakef to f so that it'll be called instead of recursing, ensuring
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# only one recursion step is performed at a time.
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encodedf = f fakef;
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opt = args:
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let
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steps = builtins.genericClosure {
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# This is how we encode a (tail) call: A set with final == false
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# and the list of arguments to pass to be found in args.
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startSet = [
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{
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key = 0;
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final = false;
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inherit args;
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}
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];
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operator =
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{ key, final, ... }@state:
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let
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# Plumbing to make genericClosure happy
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newId = {
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key = key + 1;
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};
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# Perform recursion step
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call = apply encodedf state.args;
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# If call encodes a new call, return the new encoded call,
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# otherwise signal that we're done.
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newState =
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if builtins.isAttrs call && call.__tailCall or false
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then newId // {
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final = false;
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inherit (call) args;
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} else newId // {
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final = true;
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value = call;
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};
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in
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if final
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then [ ] # end condition for genericClosure
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else [ newState ];
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};
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in
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# The returned list contains intermediate steps we ignore.
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(builtins.head (builtins.filter (x: x.final) steps)).value;
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in
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unapply argc opt;
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in
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{
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inherit (lib)
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fix
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flip
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const
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;
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inherit
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id
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rl
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rls
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lr
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lrs
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hasEllipsis
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argCount
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tailCallOpt
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apply
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unapply
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;
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}
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