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Suppose I have two very large lists {a1, a2, …} and {b1, b2, …} where all ai and bj are large sparse arrays. For the sake of memory efficiency I store each list as one comprehensive sparse array.

Now I would like to compute some function f on all possible pairs of ai and bj where each result f[ai, bj] is a sparse array again. All these sparse arrays have the same dimensions, by the way.

While

Flatten[Outer[f, {a1, a2, ...}, {b1, b2, ...}, 1], 1]

returns the desired result (in principle) it appears to consume excessive amounts of memory. Not the least because the return value is a list of sparse arrays whereas one comprehensive sparse array turns out much more efficient in my cases of interest.

Is there an efficient alternative to the above use of Outer?

More specific example:

{SparseArray[{{1, 1, 1, 1} -> 1, {2, 2, 2, 2} -> 1}],
 SparseArray[{{1, 1, 1, 2} -> 1, {2, 2, 2, 1} -> 1}],
 SparseArray[{{1, 1, 2, 1} -> 1, {2, 2, 1, 2} -> 1}],
 SparseArray[{{1, 1, 2, 2} -> -1, {2, 2, 1, 1} -> 1}],
 SparseArray[{{1, 2, 1, 1} -> 1, {2, 1, 2, 2} -> 1}],
 SparseArray[{{1, 2, 1, 2} -> 1, {2, 1, 2, 1} -> 1}],
 SparseArray[{{1, 2, 2, 1} -> -1, {2, 1, 1, 2} -> 1}],
 SparseArray[{{1, 2, 2, 2} -> 1, {2, 1, 1, 1} -> 1}]};
ByteCount[%]

list = SparseArray[%%]
ByteCount[%]

Flatten[Outer[Dot, list, list, 1], 1];
ByteCount[%]
list1x2 = SparseArray[%%]
ByteCount[%]

Flatten[Outer[Dot, list1x2, list, 1], 1];
ByteCount[%]
list1x3 = SparseArray[%%]
ByteCount[%]

etc. Not only are the raw intermediate results of Outer (lists of sparse arrays) extremely inefficient, Outer seems to consume way too much memory during the computation itself, too.

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2  
You could have made a small self contained example to illustrate your problem. Because anyone who would answer you had to do that. see sscce.org. Is his the type of example you have? len = 1000; f[x_] := SparseArray[Table[x^2, {len}]]; list1 = SparseArray[Table[RandomReal[], {len}]]; list2 = SparseArray[Table[RandomReal[], {len}]]; Timing[Outer[f, list1, list2]][[1]] –  Nasser Dec 21 '11 at 21:06
    
I'm not sure whether I understand what you mean with the phrase "comprehensive sparse array". Could you try to elaborate a bit on that? –  Sjoerd C. de Vries Dec 21 '11 at 21:19
    
@Nasser Shouldn't the function f in your example be one with two arguments? –  Sjoerd C. de Vries Dec 21 '11 at 21:20
    
@SjoerdC.deVries, I am sure you are might be correct, but that is the point of me asking. I was not sure about the question. If the user posts a small concrete example, then those who answer do not have to make up something and may be miss something in the process. –  Nasser Dec 21 '11 at 22:26
    
Just some thoughts here: Outer seems to have special support for Times: it keep the sparse structure and it's efficient. Generally, Outer[f, ...] could be made much more efficient for sparse arrays if it could be guaranteed that the f function has no side effects (and as a result f[a,b] always returns the same result for the same a and b). Then the "unspecified element" (usually 0) of the sparse array could be passed to f only once, and the result could be used as the new "unspecified element" in the new sparse array. While it can't be detected automatically that some ... –  Szabolcs Dec 22 '11 at 17:21

3 Answers 3

I will propose a solution which is rather complex but allows one to only use about twice as much memory during the computation as is needed to store the final result as a SparseArray. The price to pay for this will be a much slower execution.

The code

Sparse array construction / deconstruction API

Here is the code. First, a slightly modified (to address higher-dimensional sparse arrays) sparse array construction - deconstruction API, taken from this answer:

ClearAll[spart, getIC, getJR, getSparseData, getDefaultElement, 
  makeSparseArray];
HoldPattern[spart[SparseArray[s___], p_]] := {s}[[p]];
getIC[s_SparseArray] := spart[s, 4][[2, 1]];
getJR[s_SparseArray] := spart[s, 4][[2, 2]];
getSparseData[s_SparseArray] := spart[s, 4][[3]];
getDefaultElement[s_SparseArray] := spart[s, 3];
makeSparseArray[dims_List, jc_List, ir_List, data_List, defElem_: 0] :=
   SparseArray @@ {Automatic, dims, defElem, {1, {jc, ir}, data}};

Iterators

The following functions produce iterators. Iterators are a good way to encapsulate the iteration process.

ClearAll[makeTwoListIterator];
makeTwoListIterator[fname_Symbol, a_List, b_List] :=
  With[{indices = Flatten[Outer[List, a, b, 1], 1]},
   With[{len  = Length[indices]},
    Module[{i = 0},
      ClearAll[fname];
      fname[] := With[{ind = ++i}, indices[[ind]] /; ind <= len];
      fname[] := Null;
      fname[n_] := 
        With[{ind = i + 1}, i += n; 
           indices[[ind ;; Min[len, ind + n - 1]]] /; ind <= len];
      fname[n_] := Null;
 ]]];

Note that I could have implemented the above function more memory - efficiently and not use Outer in it, but for our purposes this won't be the major concern.

Here is a more specialized version, which produces interators for pairs of 2-dimensional indices.

ClearAll[make2DIndexInterator];
make2DIndexInterator[fname_Symbol, i : {iStart_, iEnd_}, j : {jStart_, jEnd_}] :=
   makeTwoListIterator[fname, Range @@ i, Range @@ j];
 make2DIndexInterator[fname_Symbol, ilen_Integer, jlen_Integer] :=
   make2DIndexInterator[fname, {1, ilen}, {1, jlen}];

Here is how this works:

In[14]:= 
makeTwoListIterator[next,{a,b,c},{d,e}];
next[]
next[]
next[]

Out[15]= {a,d}
Out[16]= {a,e}
Out[17]= {b,d}

We can also use this to get batch results:

In[18]:= 
makeTwoListIterator[next,{a,b,c},{d,e}];
next[2]
next[2]

Out[19]= {{a,d},{a,e}}
Out[20]= {{b,d},{b,e}}

, and we will be using this second form.

SparseArray - building function

This function will build a SparseArray object iteratively, by getting chunks of data (also in SparseArray form) and gluing them together. It is basically code used in this answer, packaged into a function. It accepts the code piece used to produce the next chunk of data, wrapped in Hold (I could alternatively make it HoldAll)

Clear[accumulateSparseArray];
accumulateSparseArray[Hold[getDataChunkCode_]] :=
  Module[{start, ic, jr, sparseData, dims, dataChunk},
   start = getDataChunkCode;
   ic = getIC[start];
   jr = getJR[start];
   sparseData = getSparseData[start];
   dims = Dimensions[start];
   While[True, dataChunk = getDataChunkCode;
     If[dataChunk === {}, Break[]];
     ic = Join[ic, Rest@getIC[dataChunk] + Last@ic];
     jr = Join[jr, getJR[dataChunk]];
     sparseData = Join[sparseData, getSparseData[dataChunk]];
     dims[[1]] += First[Dimensions[dataChunk]];
   ];
   makeSparseArray[dims, ic, jr, sparseData]];

Putting it all together

This function is the main one, putting it all together:

ClearAll[sparseArrayOuter];
sparseArrayOuter[f_, a_SparseArray, b_SparseArray, chunkSize_: 100] := 
  Module[{next, wrapperF, getDataChunkCode},
    make2DIndexInterator[next, Length@a, Length@b];
    wrapperF[x_List, y_List] := SparseArray[f @@@ Transpose[{x, y}]];
    getDataChunkCode :=
      With[{inds = next[chunkSize]},
         If[inds === Null, Return[{}]];
         wrapperF[a[[#]] & /@ inds[[All, 1]], b[[#]] & /@ inds[[All, -1]]]
      ];
    accumulateSparseArray[Hold[getDataChunkCode]]
  ];

Here, we first produce the iterator which will give us on demand portions of index pair list, used to extract the elements (also SparseArrays). Note that we will generally extract more than one pair of elements from two large input SparseArray-s at a time, to speed up the code. How many pairs we process at once is governed by the optional chunkSize parameter, which defaults to 100. We then construct the code to process these elements and put the result back into SparseArray, where we use an auxiliary function wrapperF. The use of iterators wasn't absolutely necessary (could use Reap-Sow instead, as with other answers), but allowed me to decouple the logic of iteration from the logic of generic accumulation of sparse arrays.

Benchmarks

First we prepare large sparse arrays and test our functionality:

In[49]:= 
arr = {SparseArray[{{1,1,1,1}->1,{2,2,2,2}->1}],SparseArray[{{1,1,1,2}->1,{2,2,2,1}->1}],
SparseArray[{{1,1,2,1}->1,{2,2,1,2}->1}],SparseArray[{{1,1,2,2}->-1,{2,2,1,1}->1}],
SparseArray[{{1,2,1,1}->1,{2,1,2,2}->1}],SparseArray[{{1,2,1,2}->1,{2,1,2,1}->1}]};

In[50]:= list=SparseArray[arr]
Out[50]= SparseArray[<12>,{6,2,2,2,2}]

In[51]:= larger = sparseArrayOuter[Dot,list,list]
Out[51]= SparseArray[<72>,{36,2,2,2,2,2,2}]

In[52]:= (large= sparseArrayOuter[Dot,larger,larger])//Timing
Out[52]= {0.047,SparseArray[<2592>,{1296,2,2,2,2,2,2,2,2,2,2}]}

In[53]:= SparseArray[Flatten[Outer[Dot,larger,larger,1],1]]==large
Out[53]= True

In[54]:= MaxMemoryUsed[]
Out[54]= 21347336

Now we do the power tests

In[55]:= (huge= sparseArrayOuter[Dot,large,large,2000])//Timing
Out[55]= {114.344,SparseArray[<3359232>,{1679616,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2}]}

In[56]:= MaxMemoryUsed[]
Out[56]= 536941120

In[57]:= ByteCount[huge]
Out[57]= 262021120

In[58]:= (huge1 = Flatten[Outer[Dot,large,large,1],1]);//Timing
Out[58]= {8.687,Null}

In[59]:= MaxMemoryUsed[]
Out[59]= 2527281392

For this particular example, the suggested method is 5 times more memory-efficient than the direct use of Outer, but about 15 times slower. I had to tweak the chunksize parameter (default is 100, but for the above I used 2000, to get the optimal speed / memory use combination). My method only used as a peak value twice as much memory as needed to store the final result. The degree of memory-savings as compared to Outer- based method will depend on the sparse arrays in question.

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I am not voting until I have time to test and understand this, but I was hoping you'd reply. –  Mr.Wizard Dec 23 '11 at 2:58

If lst1 and lst2 are your lists,

Reap[
   Do[Sow[f[#1[[i]], #2[[j]]]],
       {i, 1, Length@#1},
       {j, 1, Length@#2}
       ] &[lst1, lst2];
   ] // Last // Last

does the job and may be more memory-efficient. On the other hand, maybe not. Nasser is right, an explicit example would be useful.

EDIT: Using Nasser's randomly-generated arrays, and for len=200, MaxMemoryUsed[] indicates that this form needs 170MB while the Outer form in the question takes 435MB.

share|improve this answer
    
How about: Reap[Do[Sow[Dot[i, j]], {i, r}, {j, r}];] // Last // Last with r={SparseArray[],..} or Flatten[Table[Dot[i, j], {i, r}, {j, r}], 1] –  user1054186 Dec 21 '11 at 22:40

Using your example list data, I believe that you will find the ability to Append to a SparseArray quite helpful.

acc = SparseArray[{}, {1, 2, 2, 2, 2, 2, 2}]

Do[AppendTo[acc, i.j], {i, list}, {j, list}]

Rest[acc]

I need Rest to drop the first zero-filled tensor in the result. The second argument of the seed SparseArray must be the dimensions of each of your elements with a prefixed 1. You may need to explicitly specify a background for the seed SparseArray to optimize performance.

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You could use Internal`Bag stuff, depending how many of those arrays you have. –  user1054186 Dec 22 '11 at 8:24
    
@ruebenko, how does that compare to appending directly to the SparseArray? –  Mr.Wizard Dec 22 '11 at 8:37
1  
in fact it does not; Suffing Bag with SparseArray makes a Normal of the SA. I did not know that. This at least explains why Internal`Bag is only internal. It is not fully implemented for arbitrary exprs. –  user1054186 Dec 22 '11 at 14:27
    
Using acc = SparseArray[{}, {1, 2, 2, 2, 2, 2, 2}]; Do[AppendTo[acc, Dot[i, j]], {i, list}, {j, list}]; list1x2 = Rest[acc]; Clear[acc] etc. I get much worse performance in fact. For one thing, the sparse arrays list1x2, list1x3 etc. occupy more memory than their counterparts constructed via Outer above although a test reveals they are equal. Also, by the time list1x6 is being calculated the MathKernel runs out of memory while this does not happen with the Outerapproach. Any idea as to why is that? –  groovybaby Dec 22 '11 at 19:41
1  
@Mr.Wizard Tried this and it appears to be ridiculously efficient on memory… at the expense of a very slow runtime though. Well, I guess there always is a tradeoff one way or the other. Thanks for your hint! –  groovybaby Dec 25 '11 at 17:23

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