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If I want to find all possible sums from two lists list1 and list2, I use the Outer[] function with the specification of Plus as the combining operator:

In[1]= list1 = {a, b}; list2 = {c, d}; Outer[Plus, list1, list2]

Out[1]= {{a + c, a + d}, {b + c, b + d}}

If I want to be able to handle an arbitrary number of lists, say a list of lists,

In[2]= listOfLists={list1, list2};

then the only way I know how to find all possible sums is to use the Apply[] function (which has the short hand @@) along with Join:

In[3]= argumentsToPass=Join[{Plus},listOfLists]

Out[3]= {Plus, {a, b}, {c, d}}

In[4]= Outer @@ argumentsToPass

Out[4]= {{a + c, a + d}, {b + c, b + d}}

or simply

In[5]= Outer @@ Join[{Plus},listOfLists]

Out[5]= {{a + c, a + d}, {b + c, b + d}}

The problem comes when I try to compile:

In[6]= Compile[ ..... Outer @@ Join[{Plus},listOfLists] .... ]

Compile::cpapot: "Compilation of Outer@@Join[{Plus},listOfLists]] is not supported for the function argument Outer. The only function arguments supported are Times, Plus, or List. Evaluation will use the uncompiled function. "

The thing is, I am using a supported function, namely Plus. The problem seems to be solely with the Apply[] function. Because if I give it a fixed number of lists to outer-plus together, it works fine

In[7]= Compile[{{bob, _Integer, 1}, {joe, _Integer, 1}}, Outer[Plus, bob, joe]]

Out[7]= CompiledFunction[{bob, joe}, Outer[Plus, bob, joe],-CompiledCode-]

but as soon as I use Apply, it breaks

In[8]= Compile[{{bob, _Integer, 1}, {joe, _Integer, 1}}, Outer @@ Join[{Plus}, {bob, joe}]]

Out[8]= Compile::cpapot: "Compilation of Outer@@Join[{Plus},{bob,joe}] is not supported for the function argument Outer. The only function arguments supported are Times, Plus, or List. Evaluation will use the uncompiled function."

So my questions is: Is there a way to circumvent this error or, alternatively, a way to compute all possible sums of elements pulled from an arbitrary number of lists in a compiled function?

(Also, I'm not sure if "compilation" is an appropriate tag. Please advise.)

Thanks so much.

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About how many lists are you expecting, and how long are the lists? Depending on the answer, Compile may not be the fastest way to perform this operation. –  joebolte Feb 12 '11 at 0:14
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2 Answers

up vote 6 down vote accepted

One way it to use With, to create a compiled function programmatically:

Clear[makeCompiled];
makeCompiled[lnum_Integer] :=
 With[{listNames = Table[Unique["list"], {lnum}]},
   With[{compileArgs = {#, _Integer, 1} & /@ listNames},
      Compile @@ Join[Hold[compileArgs],
        Replace[Hold[Outer[Plus, listNames]], 
          Hold[Outer[Plus, {x__}]] :> Hold[Outer[Plus, x]], {0}]]]];

It can probably be done prettier, but it works. For example:

In[22]:= p2 = makeCompiled[2]
Out[22]= CompiledFunction[{list13,list14},Outer[Plus,list13,list14],-CompiledCode-]

In[23]:= p2[{1,2,3},{4,5}]
Out[23]= {{5,6},{6,7},{7,8}}

In[24]:= p3 = makeCompiled[3]
Out[24]= CompiledFunction[{list15,list16,list17},Outer[Plus,list15,list16,list17],-CompiledCode-]

In[25]:= p3[{1,2},{3,4},{5,6}]
Out[25]= {{{9,10},{10,11}},{{10,11},{11,12}}}

HTH

Edit:

You can hide the compiled function behind another one, so that it is created at run-time and you don't actually see it:

In[33]:= 
Clear[computeSums]
computeSums[lists : {__?NumberQ} ..] := makeCompiled[Length[{lists}]][lists];

In[35]:= computeSums[{1, 2, 3}, {4, 5}]

Out[35]= {{5, 6}, {6, 7}, {7, 8}}

You face an overhead of compiling in this case, since you create then a compiled function afresh every time. You can fight this overhead rather elegantly with memoization, using Module variables for persistence, to localize your memoized definitions:

In[44]:= 
Clear[computeSumsMemoized];
Module[{compiled},
  compiled[n_] := compiled[n] = makeCompiled[n];
  computeSumsMemoized[lists : {__?NumberQ} ..] := compiled[Length[{lists}]][lists]];

In[46]:= computeSumsMemoized[{1, 2, 3}, {4, 5}]

Out[46]= {{5, 6}, {6, 7}, {7, 8}}
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But wouldn't I have to recompile for all possible number of lists? I want a single compiled function which, depending on inputs, can handle different numbers of lists. –  Jess Riedel Feb 11 '11 at 20:33
1  
The latter function (computeSumsMemoized) does exactly that. When it first time sees a number of lists (say,3), that it did not see before, it does compile. But all other times that you supply 3 lists, it will not recompile - it will use the memoized definition (already compiled function). But note that for Outer, while you can get some speed-up from compilation (especially if you compile to C), it won't probably be dramatic. –  Leonid Shifrin Feb 11 '11 at 20:36
2  
Ok, sorry, I missed the point a bit. This is not a single compiled function that handles any combination of lists, indeed. Rather, this is a collection (hash-table) of compiled functions, automatically created on demand. For a single compiled function, you indeed have a problem with Apply and Outer, and I don't know off the top of my head how to solve that. But, in practice, does it make that much of a difference? You will face small performance hits due to compilation every time that you supply a new number of lists, but this will only happen once for a given number of lists. –  Leonid Shifrin Feb 11 '11 at 20:42
    
Gotcha. Boy, this seems like a complicated solution to a simple problem, but it may well be that Mathematica simply offers no better way. Thanks so much for the extensive help! –  Jess Riedel Feb 11 '11 at 20:57
2  
The problem is actually not so simple. In a procedural language, it would require nested loops with a number of loops depending on a number of input arguments - and I wouldn't know off-hand how to do this say in C or Java, given exactly this formulation (no recursion or other tricks allowed). –  Leonid Shifrin Feb 11 '11 at 21:01
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This is my first post. I hope I get this right.

If your inputs are lists of integers, I am skeptical of the value of compiling this function, at least in Mathematica 7.

For example:

f = Compile[{{a, _Integer, 1}, {b, _Integer, 1}, {c, _Integer, 1}, {d, _Integer, 1}, {e, _Integer, 1}}, 
        Outer[Plus, a, b, c, d, e]
    ];

a = RandomInteger[{1, 99}, #] & /@ {12, 32, 19, 17, 43};

Do[f @@ a, {50}] // Timing

Do[Outer[Plus, ##] & @@ a, {50}] // Timing

The two Timings are not significantly different for me, but of course this is only one sample. The point is merely that Outer is already fairly fast compared to the compiled version.

If you have reasons other than speed for compilation, you may find some use in Tuples instead of Outer, but you still have the constraint of compiled functions requiring tensor input.

f2 = Compile[{{array, _Integer, 2}}, 
      Plus @@@ Tuples@array
    ];

f2[{{1, 3, 7}, {13, 25, 41}}]

If your inputs are large, then a different approach may be in order. Given a list of lists of integers, this function will return the possible sums and the number of ways to get each sum:

f3 = CoefficientRules@Product[Sum[x^i, {i, p}], {p, #}] &;

f3[{{1, 3, 7}, {13, 25, 41}}]

This should prove to be far more memory efficient in many cases.

a2 = RandomInteger[{1, 999}, #] & /@ {50, 74, 55, 55, 90, 57, 47, 79, 87, 36};

f3[a2]; // Timing

MaxMemoryUsed[]

This took 3 seconds and minimal memory, but attempting the application of Outer to a2 terminated the kernel with "No more memory available."

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