7

Simple question, given a list like this

Clear[a, b, c, d, e, f];
lst = {{a, b}, {c, d}, {e, f}};

and suppose I have a function defined like this:

foo[x_,y_]:=Module[{},...]

And I want to apply this function to the list, so If I type

Map[foo, lst]

This gives

{foo[{a, b}], foo[{c, d}], foo[{e, f}]}

I want it to come out as

{foo[a, b], foo[c, d], foo[e, f]}

so it works.

What is the best way to do this? Assume I can't modify the function foo[] definition (say it is build-in)

Only 2 ways I know now are

Map[foo[#[[1]], #[[2]]] &, lst]
{foo[a, b], foo[c, d], foo[e, f]}

(too much work), or

MapThread[foo, Transpose[lst]]
{foo[a, b], foo[c, d], foo[e, f]}

(less typing, but need to transpose first)

Question: Any other better ways to do the above? I looked at other Map and its friends, and I could not see a function to do it more directly than what I have.

1
  • 1
    Related question: Apply list to arguments in Mathematica
    – 681234
    Jan 7, 2012 at 0:43

5 Answers 5

14

You need Apply at Level 1 or its short form, @@@

foo@@@lst    
{foo[a, b], foo[c, d], foo[e, f]}
7

One possible way is to change head of each element of lst from List to foo:

foo @@ # & /@ lst
{foo[a, b], foo[c, d], foo[e, f]}
6

Just to report puzzling performance tests of the both methods (@@@, @@ # & /@) :

        T = RandomReal[{1,100}, {1000000, 2}];

        H[F_Symbol, T_List] := 

                     First@AbsoluteTiming[F @@@ T;]/First@AbsoluteTiming[F @@ # & /@ T;]

        Table[{ToString[F], H[F, T]},  {F, {Plus, Subtract, Times, Divide, Power, Log}}]

Out[3]= {{"Plus",     4.174757}, 
         {"Subtract", 0.2596154}, 
         {"Times",    3.928230}, 
         {"Divide",   0.2674164}, 
         {"Power",    0.3148629},
         {"Log",      0.2986936}}

These results are not random, but roughly proportional for very different data sizes.

@@@ is roughly 3-4 times faster for Subtract, Divide, Power, Log while @@ # & /@ is 4 times faster for Plus and Times giving rise to another questions, which (as one can believe) could be slightly
clarified by the following evaluation:

 Attributes@{Plus, Subtract, Times, Divide, Power, Log}

Only Plus and Times have attributes Flat and Orderless, while among the rest only Power (which seems relatively the most efficient there) has also an attribute OneIdentity.

Edit

A reliable explanation to observed performance boosts (thanks to Leonid Shifrin's remarks) should go along a different route.

By default there is MapCompileLength -> 100 as we can check evaluating SystemOptions["CompileOptions"]. To reset autocompilation of Map we can evaluate :

SetSystemOptions["CompileOptions" -> "MapCompileLength" -> Infinity]

Now we can test relative performance of the both methods by evaluating once more our H - performance testing function on related symbols and list :

          Table[{ToString[F], H[F, T]}, {F, {Plus, Subtract, Times, Divide, Power, Log}}]

 Out[15]= {{"Plus",      0.2898246},
           {"Subtract",  0.2979452}, 
           {"Times",     0.2721893}, 
           {"Divide",    0.3078512}, 
           {"Power",     0.3321622},
           {"Log",       0.3258972}}

Having these result we can conclude that in general Yoda's approach (@@@) is the most efficient, while that provided by Andrei is better in case of Plus and Times due to automatic compilation of Map allowing better performance of (@@ # & /@).

9
  • 3
    Not so puzzling if we recall that Map autocompiles when it can, and Apply can be compiled for just 3 heads: Plus, Times and List. OTOH, @@@ does not autocompile. You see efficiency boosts for Plus and Times due to autocompilation in the @@#&/@ construct, and because your input is a large packed array (which allows one to benefit from autocompilation) Jan 7, 2012 at 6:38
  • 1
    See also this answer of mine: stackoverflow.com/questions/6405304/…, and the comments below it, for more discussion of similar matters. Jan 7, 2012 at 13:00
  • @Leonid Thank You for interesting link and comments. Indeed, when I evaluate my H function on T1 = FromPackedArray[T] relative efficiency of Plus and Times slows down roughly by the factor 2, while the other functions only by a few percents, however Map is still almost two times faster for Plus and Times. The reason of this effect is apparently autocompilation. On the other hand, remarks on Attributes of related functions are still valid and I hope there shouldn't be any kind of misunderstanding.
    – Artes
    Jan 7, 2012 at 19:49
  • 1
    Frankly, I think that autocompilation is the sole reason for the performance difference, while other attributes you mention don't contribute to it in this particular case. To see that, execute SetSystemOptions["CompileOptions" -> "MapCompileLength" -> Infinity] - this effectively disables auto-compilation. Then redo your timings and you will see that Times and Plus now behave the same as the rest (make sure to restore "MapCompileLength" to its default (100)).To be sure, attributes can make a difference, but not in this case I guess. Jan 7, 2012 at 20:33
  • Thank You for helpful comments. What to do in case one would like to set permanently different MapCompileLength, ...Option Inspector ? I guess this is not recommended. Have you tried to do it ?
    – Artes
    Jan 8, 2012 at 7:29
4

A few more possibilities to pick from:

This one is a more verbose version of yoda's answer. It applies foo at level 1 of the list lst only (replaces the head List with the head foo):

Apply[foo, lst, {1}]

This does the same, but maps Apply over the list lst (essentially Andrei's answer):

Map[Apply[foo, #] &, lst ]

And this just replaces the pattern List[x__] with foo[x] at level 1:

Replace[lst, List[x__] -> foo[x], 1]
3

The answers on Apply[] are spot on, and is the right thing to do, but what you were trying to do, was to replace a List[] head with a Sequence[] head, i.e. List[List[3,5],List[6,7]] should become List[Sequence[3,5],Sequence[6,7]].

Sequence head is what naturally remains if a head of any list of parameters is deleted, so Delete[Plus[3,5],0] and Delete[{3,5},0] and Delete[List[3,5],0] would all produce Sequence[3,5].

So foo@Delete[#,0]&/@{{a, b}, {c, d}, {e, f}} will give you the same as foo@@@{{a, b}, {c, d}, {e, f}}.

Alternatively, foo[#/.List->Sequence]&/@{{a, b}, {c, d}, {e, f}} does the same thing.

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    I have to disagree with the statement that he wants to turn List[List[...] ..] into List[Sequence[...] ..]. More correctly, he wants List[f[...] ..], i.e. he wants to change the heads of the inner lists to f.
    – rcollyer
    Jan 7, 2012 at 2:21
  • I agree that this is what he ultimately "wants". I meant to say it in a sense "what you want to do to get there is..." ;-) Sorry for the confusion. To get to List[f[Sequence[...]], ...] he needed a way to convert a list of lists to a list of sequences. Apply does it internally. Jan 7, 2012 at 3:53

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