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How can one add the number of powers of x in expressions like the following?

x^2f[x]g[x^3]

or

x^2g[x^4]

or

x^2g[x^2f[x^2]]

The counting is such that all these examples must return 6. I was thinking of using Count with some pattern, but I didn't manage to construct a pattern for this.

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1  
write a parser? –  Mitch Wheat Dec 17 '11 at 8:30
    
@MitchWheat I looked up parser in the Mathematica help and at Wikipedia. Also I searched for parser + Mathematica in Stack Overflow, but it seems all rather abstract or technical to me. Can you give me a simple example of a parser in Mathematica? –  sjdh Dec 17 '11 at 8:44
    
What should the (x y)^2 return, 1 or 2? What about something like f[x, x^2]? Should it return 3? –  Simon Dec 17 '11 at 11:16
1  
@Simon (x y)^2 should return 2 and f[x, x^2] should return 3 indeed. –  sjdh Dec 17 '11 at 11:39
    
@sjdh: In which case both my answer and Mr.W's answer work ok. –  Simon Dec 17 '11 at 11:40

2 Answers 2

up vote 3 down vote accepted

Here's my quick hack - some of the behaviour (see the final example) might not be quite what you want:

SetAttributes[countPowers, Listable]
countPowers[expr_, symb_] := Module[{a}, 
  Cases[{expr} /. symb -> symb^a // PowerExpand, symb^n_ :> n, 
        Infinity] /. a -> 1 // Total]

Then

In[3]:= countPowers[{x^2 f[x] g[x^3], x^2 g[x^4], x^2 g[x^2 f[x^2]]}, x]

Out[3]= {6, 6, 6}

and

In[4]:= countPowers[{x^(2 I)  g[x^3], g[x, x^4], 
                       x^2 g[E^(2 Pi I x) , f[x]^x]}, x]

Out[4]= {3 + 2 I, 5, 5}
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Interesting. My version appears cleaner, but does it work? I am having trouble following this one. –  Mr.Wizard Dec 17 '11 at 11:30
    
I think I understand it now, and we had the same idea, but this method introduces unneeded complexity unless mine misses something. –  Mr.Wizard Dec 17 '11 at 11:38
    
Yeah, my version is shit. Your soln is about 7 times faster and much neater. I originally tried to modify ruebenko's answer to use the a default x^n_., but then the x^n contributed both as x and x^n... so I saw red and hit it with PowerExpand. –  Simon Dec 17 '11 at 11:39
    
I wouldn't say that; it's just a little rough. –  Mr.Wizard Dec 17 '11 at 11:42
    
Deja vu: stackoverflow.com/questions/5803432/… –  Mr.Wizard Dec 17 '11 at 11:50

Since you want to count x as an implicit power of 1, you could use this:

powerCount[x_Symbol][expr_] := 
  Tr @ Reap[PowerExpand[expr] /. {x^n_ :> Sow[n], x :> Sow[1]}][[2,1]]

powerCount[x] /@
  {
   x^2f[x]g[x^3],
   x^2g[x^4],
   x^2g[x^2f[x^2]]
  }
{6, 6, 6}

Alternatively, this could be written without Sow and Reap if that makes it easier to read:

powerCount[x_Symbol][expr_] := 
  Module[{t = 0}, PowerExpand[expr] /. {x^n_ :> (t += n), x :> t++}; t]

Either form can be made more terse using vanishing patterns, at the possible expense of clarity:

powerCount[x_Symbol][expr_] := 
  Tr @ Reap[PowerExpand[expr] /. x^n_ | x :> Sow[1 n]][[2, 1]]
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How about powerCount[x][(x y)^(1/2)]? –  Simon Dec 17 '11 at 11:54
    
@Simon given the examples I decided to handle only non-compound instances of x but I suppose a case like that should be handled for robustness. Does PowerExpand suffice? –  Mr.Wizard Dec 17 '11 at 11:59
    
It depends if the OP cares about such cases. As it is, you have probably satisfied his original request. Especially since f[x^2] should return 2, even though f could be any old crazy function. The OP's request does not make sense mathematically, so a syntactic reading is fine. –  Simon Dec 17 '11 at 12:03
    
@Simon well, I added PowerExpand -- I'll leave it unless it is likely to cause trouble somewhere (I haven't thought that through.) –  Mr.Wizard Dec 17 '11 at 12:06
    
Your "vanishing patterns" still make me feel a little uncomfortable... –  Simon Dec 17 '11 at 12:50

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