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I need to evaluate a sum over Cartesian product of variable number of sets. Assuming f[...] is a multivariate function, define

p[A__set] :=  Module[{Alist, args, iterators,it},
  Alist = {A};
  i = 1;
  iterators = {it[i++], Level[#1, 1]} & /@ Alist;
  args = Table[it[i], {i, Range[Length[Alist]]}];
  Sum[f@@ args, Sequence @@ iterators ]

But then

p[set[1, 2, 3], set[11, 12, 13]]

Gives the error: Sum::vloc: "The variable Sequence@@iterators cannot be localized so that it can be assigned to numerical values."

The following hack works:

p[A__set] :=  Module[{Alist, args, iterators,it,TmpSymbol},
  Alist = {A};
  i = 1;
  iterators = {it[i++], Level[#1, 1]} & /@ Alist;
  args = Table[it[i], {i, Range[Length[Alist]]}];
  Sum@@TmpSymbol[f @@ args, Sequence @@ iterators ]


p[set[1, 2, 3], set[11, 12]]

gives what I want:

f[1, 11] + f[1, 12] + f[2, 11] + f[2, 12] + f[3, 11] + f[3, 12]

I would like to know why the original does not.

As per belisarius there is much more elegant way to do this:

p[A__set] := Total[Outer[f, A],Length[{A}]];
share|improve this question

2 Answers 2

up vote 3 down vote accepted

This has to do with evaluation order. Please see Tutorial: Evaluation as a reference.

Sum has the Attribute HoldAll:

{HoldAll, Protected, ReadProtected}

Because of this only arguments with certain heads such as Evaluate or Sequence or Symbols with upvalues will evaluate. You may think that your argument Sequence @@ iterators has the head Sequence, but it actually has the head Apply:

HoldForm @ FullForm[Sequence @@ iterators]
Apply[Sequence, iterators]

Sum expects literal arguments that match its declared syntax, and thus your code fails. You can force evaluation in several different ways. Arguably the most transparent is to add Evaluate:

iterators = {{a, 1, 3}, {b, 5, 7}};

Sum[a^2/b, Evaluate[Sequence @@ iterators]]

More concisely you can leverage Function, SlotSequence, and Apply; evaluation takes place since neither Apply, nor Function by default, has HoldAll:

Sum[a^2/b, ##] & @@ iterators

Both of these have a potential problem however: if a or b received a global value the Symbol in the definition of iterators will evaluate to this value causing another error:

a = 0;

Sum[a^2/b, ##] & @@ iterators

Sum::itraw: Raw object 0 cannot be used as an iterator. >>

Instead you can store the iterator lists in a Hold expression and use the "injector pattern" to insert these values without complete evaluation:

iterators = Hold[{a, 1, 3}, {b, 5, 7}];

iterators /. _[x__] :> Sum[a^2/b, x]

Alternatively you could define iterators as an upvalue:

Sum[args___, iterators] ^:= Sum[args, {a, 1, 3}, {b, 5, 7}]

Now simply:

Sum[a^2/b, iterators]

Please see my answers to Keep function range as a variable on Mathematica.SE for more examples, as this question is closely related. Specifically see setSpec in my second answer which automates the upvalue creation.

share|improve this answer
That's it, thank you. It is not clear to me what is the reason for the Sum to HoldAll rather then HoldFirst. –  user1672572 Dec 15 '13 at 16:36
I've got it. It's so that the variable in the iterator does not evaluate to something it was previously assigned. Though, it could have been left to the user to take care of. –  user1672572 Dec 15 '13 at 17:19
@user Yes, that's the reason. I think you will find that it is easier (and less commonly needed) to force evaluation as shown above than it would be to prevent evaluation. I think it was a good design choice, but it could be better explained in the documentation. Behavior is similar in other functions that take an iterator specification; try: Attributes /@ {Table, Do, Product, Plot, ParametricPlot, FindRoot} –  Mr.Wizard Dec 16 '13 at 2:18

There are many easier ways do that in Mathematica:

Total[Outer[f, {1, 2, 3}, {11, 12}, {a, b}],3]
f[1, 11, a] + f[1, 11, b] + f[1, 12, a] + f[1, 12, b] +
f[2, 11, a] + f[2, 11, b] + f[2, 12, a] + f[2, 12, b] + 
f[3, 11, a] + f[3, 11, b] + f[3, 12, a] + f[3, 12, b]
share|improve this answer
Very cool, thanks. p[A__set] := Total[Flatten[Outer[f, A]]] does the job. Not the answer to my question, though. –  user1672572 Dec 13 '13 at 23:24

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