Given a list containing k
sublists, let
A={{a1,a2,a3,...},{b1,b2,b3,...},...}
, I want to sort those sublists by their Total[A[i]]
. Is there any efficient way to make this?
Note that in many cases, sorting based on Ordering
can be faster than SortBy
, because it allows us to leverage vectorization. In this particular case, the speedup is not that huge:
In[50]:= test = RandomInteger[10,{5000000,5}];
In[54]:= (res1=SortBy[test,{Total}]);//Timing
(res2 = test[[Ordering[Total[test,{2}]]]]);//Timing
res1===res2
Out[54]= {1.422,Null}
Out[55]= {1.125,Null}
Out[56]= True
But, this is because Total
is a builtin function. The whole reason why SortBy
was introduced, is efficiency (that is, for a single comparison function. For several comparison functions as tiebreakers, also convenience). It is more efficient that Sort
, because it is more specific, and therefore bypasses more steps in the main evaluation sequence. However, there is no way for SortBy
to leverage the possible listability (vectorized nature) of the function on which the sorting is based  it is applied to list elements onebyone. The solution with ordering does explicitly leverage the possibility of wholesale computation of the sorting function (in this case, Total[#,{2}]&
does this), and therefore is faster.
If, for example, the task would be to sort according to a total of the second, third and fourth element in each sublist, we'd see a larger performance difference:
In[60]:= (res3=SortBy[test,{Total[#[[2;;4]]]&}]);//Timing
(res4=test[[Ordering[Total[test[[All,2;;4]],{2}]]]]);//Timing
res3==res4
Out[60]= {2.39,Null}
Out[61]= {1.11,Null}
Out[62]= True
Generally, the performance boost will be the largest for sorting functions which are both computationally intensive and vectorized, and such that they are much faster when applied to the whole list. Note, however, that the performance boost for sorting will never be as large as for the sorting function itself, for large lists. This is because of the intrinsic complexity of sorting, which is proportional to n*Log[n]
for large lists of length n
, and this complexity will always be there.
Check SortBy
in documentation for a range of possibilities to sort lists of lists.
SortBy[A,Total]
gives what you need.
EDIT: Per Mr. Wizard's comment below and the explanation in the link therein,
SortBy[A,{Total}]
is better.

@Mr Wizard commented the other day about another sorting problem and it seems that
SortBy[A, {Total}]
would be slightly faster for this. – Mike Honeychurch Jan 17 '12 at 6:13 
Thank you @Mike. Very interesting; it sounds like a vintage Mr.Wizard discovery. Do you remember the question or the link? – kglr Jan 17 '12 at 6:32

not offhand other than it was in the last 34 days and a question related to sorting. Have to go now otherwise I would look for it. – Mike Honeychurch Jan 17 '12 at 6:44

2@kguler it is not my discovery; it produces a stable sort without tiebreaking, as explained by Andrew Moylan. It logically follows that if there are a lot of ties this will be faster. It also changes the result that you get, so please be aware of what you are doing. – Mr.Wizard Jan 17 '12 at 8:03

@Mr.Wizard, thank you so much for the link. I did notice the results changing and puzzled by it; now it makes sense. – kglr Jan 17 '12 at 8:18
The following should work (but I can't test it right now):
Sort[A, Total[#1]<Total[#2]&]