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 (@@ # & /@
).