This is a complete rewrite of my previous answer. It turns out that in my previous attempts, I overlooked a much simpler method based on a combination of packed arrays and sparse arrays, that is much faster and more memory - efficient than all previous methods (at least in the range of sample sizes where I tested it), while only minimally changing the original `SubValues`

- based approach. Since the question was asked about the most efficient method, I will remove the other ones from the answer (given that they are quite a bit more complex and take a lot of space. Those who would like to see them can inspect past revisions of this answer).

### The original `SubValues`

- based approach

We start by introducing a function to generate the test samples of configurations for us. Here it is:

```
Clear[generateConfigurations];
generateConfigurations[maxIndex_Integer, maxConfX_Integer, maxConfY_Integer,
nconfs_Integer] :=
Transpose[{
RandomInteger[{1, maxIndex}, nconfs],
Transpose[{
RandomInteger[{1, maxConfX}, nconfs],
RandomInteger[{1, maxConfY}, nconfs]
}]}];
```

We can generate a small sample to illustrate:

```
In[3]:= sample = generateConfigurations[2,2,2,10]
Out[3]= {{2,{2,1}},{2,{1,1}},{1,{2,1}},{1,{1,2}},{1,{1,2}},
{1,{2,1}},{2,{1,2}},{2,{2,2}},{1,{2,2}},{1,{2,1}}}
```

We have here only 2 indices, and configurations where both "x" and "y" numbers vary from 1 to 2 only - 10 such configurations.

The following function will help us imitate the accumulation of frequencies for configurations, as we increment `SubValues`

-based counters for repeatedly occurring ones:

```
Clear[testAccumulate];
testAccumulate[ff_Symbol, data_] :=
Module[{},
ClearAll[ff];
ff[_][_] = 0;
Do[
doSomeStuff;
ff[#1][#2]++ & @@ elem;
doSomeMoreStaff;
, {elem, data}]];
```

The `doSomeStuff`

and `doSomeMoreStaff`

symbols are here to represent some code that might preclude or follow the counting code. The `data`

parameter is supposed to be a list of the form produced by `generateConfigurations`

. For example:

```
In[6]:=
testAccumulate[ff,sample];
SubValues[ff]
Out[7]= {HoldPattern[ff[1][{1,2}]]:>2,HoldPattern[ff[1][{2,1}]]:>3,
HoldPattern[ff[1][{2,2}]]:>1,HoldPattern[ff[2][{1,1}]]:>1,
HoldPattern[ff[2][{1,2}]]:>1,HoldPattern[ff[2][{2,1}]]:>1,
HoldPattern[ff[2][{2,2}]]:>1,HoldPattern[ff[_][_]]:>0}
```

The following function will extract the resulting data (indices, configurations and their frequencies) from the list of `SubValues`

:

```
Clear[getResultingData];
getResultingData[f_Symbol] :=
Transpose[{#[[All, 1, 1, 0, 1]], #[[All, 1, 1, 1]], #[[All, 2]]}] &@
Most@SubValues[f, Sort -> False];
```

For example:

```
In[10]:= result = getResultingData[ff]
Out[10]= {{2,{2,1},1},{2,{1,1},1},{1,{2,1},3},{1,{1,2},2},{2,{1,2},1},
{2,{2,2},1},{1,{2,2},1}}
```

To finish with the data-processing cycle, here is a straightforward function to extract data for a fixed index, based on `Select`

:

```
Clear[getResultsForFixedIndex];
getResultsForFixedIndex[data_, index_] :=
If[# === {}, {}, Transpose[#]] &[
Select[data, First@# == index &][[All, {2, 3}]]];
```

For our test example,

```
In[13]:= getResultsForFixedIndex[result,1]
Out[13]= {{{2,1},{1,2},{2,2}},{3,2,1}}
```

This is presumably close to what @zorank tried, in code.

### A faster solution based on packed arrays and sparse arrays

As @zorank noted, this becomes slow for larger sample with more indices and configurations. We will now generate a large sample to illustrate that (**note! This requires about 4-5 Gb of RAM, so you may want to reduce the number of configurations if this exceeds the available RAM**):

```
In[14]:=
largeSample = generateConfigurations[20,500,500,5000000];
testAccumulate[ff,largeSample];//Timing
Out[15]= {31.89,Null}
```

We will now extract the full data from the `SubValues`

of `ff`

:

```
In[16]:= (largeres = getResultingData[ff]); // Timing
Out[16]= {10.844, Null}
```

This takes some time, but one has to do this only once. But when we start extracting data for a fixed index, we see that it is quite slow:

```
In[24]:= getResultsForFixedIndex[largeres,10]//Short//Timing
Out[24]= {2.687,{{{196,26},{53,36},{360,43},{104,144},<<157674>>,{31,305},{240,291},
{256,38},{352,469}},{<<1>>}}}
```

The main idea we will use here to speed it up is to pack individual lists inside the `largeres`

, those for indices, combinations and frequencies. While the full list can not be packed, those parts individually can:

```
In[18]:= Timing[
subIndicesPacked = Developer`ToPackedArray[largeres[[All,1]]];
subCombsPacked = Developer`ToPackedArray[largeres[[All,2]]];
subFreqsPacked = Developer`ToPackedArray[largeres[[All,3]]];
]
Out[18]= {1.672,Null}
```

This also takes some time, but it is a one-time operation again.

The following functions will then be used to extract the results for a fixed index much more efficiently:

```
Clear[extractPositionFromSparseArray];
extractPositionFromSparseArray[HoldPattern[SparseArray[u___]]] := {u}[[4, 2, 2]]
Clear[getCombinationsAndFrequenciesForIndex];
getCombinationsAndFrequenciesForIndex[packedIndices_, packedCombs_,
packedFreqs_, index_Integer] :=
With[{positions =
extractPositionFromSparseArray[
SparseArray[1 - Unitize[packedIndices - index]]]},
{Extract[packedCombs, positions],Extract[packedFreqs, positions]}];
```

Now, we have:

```
In[25]:=
getCombinationsAndFrequenciesForIndex[subIndicesPacked,subCombsPacked,subFreqsPacked,10]
//Short//Timing
Out[25]= {0.094,{{{196,26},{53,36},{360,43},{104,144},<<157674>>,{31,305},{240,291},
{256,38},{352,469}},{<<1>>}}}
```

We get a 30 times speed-up w.r.t. the naive `Select`

approach.

### Some notes on complexity

Note that the second solution is faster because it uses optimized data structures, but its complexity is the same as that of `Select`

- based one, which is, linear in the length of total list of unique combinations for all indices. Therefore, in theory, the previously - discussed solutions based on nested hash-table etc *may* be asymptotically better. The problem is, that in practice we will probably hit the memory limitations long before that. For the 10 million configurations sample, the above code was still 2-3 times faster than the fastest solution I posted before.

**EDIT**

The following modification:

```
Clear[getCombinationsAndFrequenciesForIndex];
getCombinationsAndFrequenciesForIndex[packedIndices_, packedCombs_,
packedFreqs_, index_Integer] :=
With[{positions =
extractPositionFromSparseArray[
SparseArray[Unitize[packedIndices - index], Automatic, 1]]},
{Extract[packedCombs, positions], Extract[packedFreqs, positions]}];
```

makes the code twice faster still. Moreover, for more sparse indices (say, calling the sample-generation function with parameters like `generateConfigurations[2000, 500, 500, 5000000]`

), the speed-up with respect to the `Select`

- based function is about *100* times.

`SubValues`

, nor for`NValues`

,`FormatValues`

and`DefaultValues`

. There is one for`UpValues`

,`DownValues`

and`OwnValues`

. Not sure whether we should conclude from this that we aren't supposed to use`SubValues`

. – Sjoerd C. de Vries Aug 31 '11 at 12:34`SubValues`

would be if one could not exclude the possibility that their support could be dropped in the future. But I would bet anything that this would never happen. – Leonid Shifrin Aug 31 '11 at 14:07`SubValues`

rule! (And may contain`Rules`

!) – telefunkenvf14 Sep 2 '11 at 17:15