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I'm puzzled by Mathematica's responses to the following:

ClearAll[n]
#^2 & /@ Range[n]
#^2 & /@ Range[n] // StandardForm

Range1

It seems that even Mathematica (8.0) doesn't believe what it has just said:

#^2 & /@ Range[5]
Range[5^2]

Range2

Any thoughts about what is happening?

Edit:

The original context for this question was the following. I had written

PrimeOmega[Range[n]] - PrimeNu[Range[n]]

and since n was going to be very large (2^50), I thought I might save time by rewriting it as:

 PrimeOmega[#] - PrimeNu[#] &/@Range[n]

Thinking back, that probably wasn't such a good idea. (I could have used Module to 'compute' the Range only once.)

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1  
Regarding the edit part - I am afraid you won't find a machine with enough memory to hold Range[2^50]. Do you really need all those numbers, and also at the same time? –  Leonid Shifrin Oct 14 '11 at 15:43
    
@Leonid. Not at the same time. I suppose I could loop and keep a running total of the difference, say, by using Sum. –  David Carraher Oct 14 '11 at 16:09
    
Are you perhaps confusing Range[5^2] for Range[5]^2? As for 2^50, "What Leonid said". –  Daniel Lichtblau Oct 14 '11 at 16:12
    
@David I see. If you only need the total of the difference, it will be faster to move in large chunks, say a few millions numbers or so. Or, alternatively, you can compile a loop to "C". But, I did a few experiments, and it seems that even for 10^4 first integers, you need about 0.5 sec. both ways. The bottleneck seems in the Prime - functions themselves. Whether or not one can implement them much faster by hand (say, using Compile, or writing in C and loading as dll), I don't know, but, to work for your numbers, they must be very much faster. –  Leonid Shifrin Oct 14 '11 at 16:19
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@LeonidShifrin It is FactorInteger behind the scenes that is the bottleneck. For numbers in that size range I doubt one will gain much unless it is by using similar methods but better tuning heuristics e.g. for cut-offs. Possibly of interest (coincidently from just two days ago): lists.apple.com/archives/scitech/2011/Oct/msg00009.html –  Daniel Lichtblau Oct 14 '11 at 16:39

2 Answers 2

up vote 15 down vote accepted

Since n is undefined, Range[n] evaluated to itself. Therefore, Map acts on it as on any other symbolic head, mapping your function on its elements - here it is just n

In[11]:= #^2 & /@ someHead[n]
Out[11]= someHead[n^2]

EDIT

Addressing the question in your edit - for numeric n, Range evaluates to a list all right, and you get the expected result (which is, Range[5]^2. It is all about the order of evaluation. To get Range[5^2], you could have used #^2&/@Unevaluated[Range[5]], in which case everything happens just like for symbolic n above) . In fact, Range issues an error message on non-numeric input. Also, it is tangential to the question, but functions like #^2& are Listable, and you don't have to map them.

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+1 I believe you are due for a Gold badge now. :-) –  Mr.Wizard Oct 14 '11 at 15:10
    
@Mr.Wizard not quite yet... –  Leonid Shifrin Oct 14 '11 at 15:17
    
Leonid, how so? –  Mr.Wizard Oct 14 '11 at 15:17
1  
@yoda As always, the truth is simple. I am on the contract with the leading popcorn supplier to our SO tag, that's all. –  Leonid Shifrin Oct 14 '11 at 15:39
3  
@DavidCarraher I was referring to Leonid's comment that he's in cahoots with the popcorn suppliers, which is why he keeps deleting his answers on Stack Overflow, further delaying his inevitable Gold badge, thereby keeping us all on the edge of our seats, leading us to consume more popcorn in anticipation of the big day, causing an increase in popcorn sales, which will eventually make its way back into his pocket. Phew! That was a mess. –  r.m. Oct 14 '11 at 16:22

Slightly off topic, but you can improve the speed by redefining in terms of FactorInteger, which then is only called once per input.

f1[n_] := PrimeOmega[Range[n]] - PrimeNu[Range[n]]
f2[n_] := With[{fax=FactorInteger[#]}, Total[fax[[All,2]]]-Length[fax]]& /@ Range[n]

Example:

In[27]:= Timing[pdiff1 = f1[2^20];]
Out[27]= {37.730264, Null}

In[28]:= Timing[pdiff2 = f2[2^20];]
Out[28]= {9.364576, Null}

In[29]:= pdiff1===pdiff2
Out[29]= True

Daniel Lichtblau

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+1 These results really surprised me. I would have thought just the opposite! –  David Carraher Oct 14 '11 at 18:09
1  
@DavidCarraher [You mean pdigg2===pdiff1???] In seriousness, what surprises me is that they seem to be a factor of 4 rather than 2 apart. I have confirmed (for at least a couple of cases) that PrimeOmega and PrimeNu each call FactorInteger exactly one time, so I do not see why that first is 4x slower. And it happens even if I reverse the order, so it is not a caching phenomenon in any respect. –  Daniel Lichtblau Oct 14 '11 at 18:58

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