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I want to write a

 Module Arg[f_,n_] 

that takes a function f (having <=n arguments) and a natural number n and outputs the n-th argument of the function f.

As an example, suppose that f is defined by

f[a_,b_]=a^2+b^2. 

Then,

Arg[f[s,t],1] 

should be s;

while

Arg[f[u,v],2] 

should be v.

My question is whether this is possible. If so, what should I write in the place of "???" below?

Arg[f_,n_] := Module[{}, ??? ]

Note that I don't want to specify a_ and b_ in the definition of Arg like

 Arg[f_,a_,b_,n_]

EDIT: "Arg" is just my name for the module not the internal function Arg of Mathematica.

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You realize Arg is an internal function, right? Did you mean to rewrite Arg (doesn't look like it from the definition) or was it just a poor choice of function name? Also, you probably meant Arg[f[u,v],2] gives v? –  r.m. Nov 19 '11 at 23:15
    
You just bungled up my edits @bel :) –  r.m. Nov 19 '11 at 23:17
    
@yoda Sorry :(. I'm having some trouble with JS on my browser. perhaps that is why I did not receive the "previous edit" notice. Feel free to rollback my changes or merge them with yours. –  belisarius Nov 19 '11 at 23:27
    
@belisarius Nah, no worries :) –  r.m. Nov 19 '11 at 23:30
    
Thank you for the edits and the answers. –  Cantor Nov 20 '11 at 15:17

2 Answers 2

up vote 10 down vote accepted

Perhaps

SetAttributes[arg, HoldFirst];
arg[f_[x___], n_] := {x}[[n]]

f[a_, b_] := a^2 + b^2.
arg[f[arg[f[s, t], 1], t], 1]
arg[f[s, t], 2]

(*
 -> s
 -> t
*)

arg[ArcTan[f[Cos@Sin@x, x], t], 1]

(*
->  x^2. + Cos[Sin[x]]^2
*)
share|improve this answer

Assuming your second example should give u, this should do the job:

ClearAll[arg];
SetAttributes[arg, HoldFirst];
arg[g_, n_] := Module[
  {tmp, ret},
  Unprotect[Part];
  tmp = Attributes[Part];
  SetAttributes[Part, HoldFirst];
  ret = Part[g, n];
  ClearAttributes[Part, HoldFirst];
  SetAttributes[Part, tmp];
  Protect[Part];
  ret
  ]

so that

f[a_, b_] = a^2 + b^2.;
arg[f[s, t], 1]

gives s.

This is very heavy-handed though, so I expect someone will find something better soon enough.

This is a bit better (doesn't redefine built-in functions even temporarily):

ClearAll[arg2];
SetAttributes[arg2, HoldFirst];
arg2[g_, n_] := Hold[g][[1, n]]
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