What the heck, I'll join the party. Here is my version:

```
Flatten/@Flatten[Thread/@Transpose@{#,Mean/@#[[All,All,2]]}&@GatherBy[e,First],1]
```

Should be fast enough I guess.

**EDIT**

In response to the critique of @Mr.Wizard (my first solution was reordering the list), and to explore a bit the high-performance corner of the problem, here are 2 alternative solutions:

```
getMeans[e_] :=
Module[{temp = ConstantArray[0, Max[#[[All, 1, 1]]]]},
temp[[#[[All, 1, 1]]]] = Mean /@ #[[All, All, 2]];
List /@ temp[[e[[All, 1]]]]] &[GatherBy[e, First]];
getMeansSparse[e_] :=
Module[{temp = SparseArray[{Max[#[[All, 1, 1]]] -> 0}]},
temp[[#[[All, 1, 1]]]] = Mean /@ #[[All, All, 2]];
List /@ Normal@temp[[e[[All, 1]]]]] &[GatherBy[e, First]];
```

The first one is the fastest, trading memory for speed, and can be applied when keys are all integers, *and* your maximal "key" value (2 in your example) is not too large. The second solution is free from the latter limitation, but is slower. Here is a large list of pairs:

```
In[303]:=
tst = RandomSample[#, Length[#]] &@
Flatten[Map[Thread[{#, RandomInteger[{1, 100}, 300]}] &,
RandomSample[Range[1000], 500]], 1];
In[310]:= Length[tst]
Out[310]= 150000
In[311]:= tst[[;; 10]]
Out[311]= {{947, 52}, {597, 81}, {508, 20}, {891, 81}, {414, 47},
{849, 45}, {659, 69}, {841, 29}, {700, 98}, {858, 35}}
```

The keys can be from 1 to 1000 here, 500 of them, and there are 300 random numbers for each key. Now, some benchmarks:

```
In[314]:= (res0 = getMeans[tst]); // Timing
Out[314]= {0.109, Null}
In[317]:= (res1 = getMeansSparse[tst]); // Timing
Out[317]= {0.219, Null}
In[318]:= (res2 = tst[[All, {1}]] /.
Reap[Sow[#2, #] & @@@ tst, _, # -> Mean@#2 &][[2]]); // Timing
Out[318]= {5.687, Null}
In[319]:= (res3 = tst[[All, {1}]] /.
Dispatch[
Reap[Sow[#2, #] & @@@ tst, _, # -> Mean@#2 &][[2]]]); // Timing
Out[319]= {0.391, Null}
In[320]:= res0 === res1 === res2 === res3
Out[320]= True
```

We can see that the `getMeans`

is the fastest here, `getMeansSparse`

the second fastest, and the solution of @Mr.Wizard is somewhat slower, but only when we use `Dispatch`

, otherwise it is much slower. Mine and @Mr.Wizard's solutions (with Dispatch) are similar in spirit, the speed difference is due to (sparse) array indexing being more efficient than hash look-up. Of course, all this matters only when your list is really large.

**EDIT 2**

Here is a version of `getMeans`

which uses `Compile`

with a C target and returns numerical values (rather than rationals). It is about twice faster than `getMeans`

, and the fastest of my solutions.

```
getMeansComp =
Compile[{{e, _Integer, 2}},
Module[{keys = e[[All, 1]], values = e[[All, 2]], sums = {0.} ,
lengths = {0}, , i = 1, means = {0.} , max = 0, key = -1 ,
len = Length[e]},
max = Max[keys];
sums = Table[0., {max}];
lengths = Table[0, {max}];
means = sums;
Do[key = keys[[i]];
sums[[key]] += values[[i]];
lengths[[key]]++, {i, len}];
means = sums/(lengths + (1 - Unitize[lengths]));
means[[keys]]], CompilationTarget -> "C", RuntimeOptions -> "Speed"]
getMeansC[e_] := List /@ getMeansComp[e];
```

The code `1 - Unitize[lengths]`

protects against division by zero for unused keys. We need every number in a separate sublist, so we should call `getMeansC`

, not `getMeansComp`

directly. Here are some measurements:

```
In[180]:= (res1 = getMeans[tst]); // Timing
Out[180]= {0.11, Null}
In[181]:= (res2 = getMeansC[tst]); // Timing
Out[181]= {0.062, Null}
In[182]:= N@res1 == res2
Out[182]= True
```

This can probably be considered a heavily optimized numerical solution. The fact that the fully general, brief and beautiful solution of @Mr.Wizard is only about 6-8 times slower speaks very well for the latter general concise solution, so, unless you want to squeeze every microsecond out of it, I'd stick with @Mr.Wizard's one (with `Dispatch`

). But it's important to know how to optimize code, and also to what degree it can be optimized (what can you expect).

`d[[10 ;; 20]]`

should be`d[[11 ;; 20]]`

– Mr.Wizard May 25 '11 at 15:02