This is a design issue I came across while working on implementation of Generalized Distributive Law. Suppose you need to automatically generate expressions of the following form

Terms inside the sum, fixed variables and "summed over" variables are automatically generated for each such expression, and "f" functions are defined separately. To generate expression above, I may need to call

```
sumProduct(factors,fixedVariables,fixedValues,freeVariables,freeRanges)
```

where

```
factors={{1,4},{3,4},{3,4,5}}
fixedVariables={1,3}
fixedValues={-1,9}
freeVariables={4,5}
freeRanges={Range[5],Range[6]}
```

and the output of that function will be equivalent to

```
Total[{f14[-1,1]f34[9,1]f345[9,1,1],f14[-1,2]f34[9,2]f345[9,2,1],....}]
```

Representation of f terms could be different, ie f[{1,4},{-1,1}] instead of f14[-1,1]. Also using Integer to refer to each variable is just one design choice.

Can anyone suggest an elegant approach to implementing sumProduct?

**Edit 11/11**
Janus' solution, rewritten for readability

```
factors = {{1, 4}, {3, 4}, {3, 4, 5}};
vars = {{1, {-1}}, {3, {9}}, {4, Range[5]}, {5, Range[6]}};
(* list of numbers => list of vars *)
arglist[factor_] := Subscript[x, #] & /@ factor;
(* list of factors => list of functions for those factors *)
terms = Apply[f[#], arglist[#]] & /@ factors;
(* {var,range} pairs for each variable *)
args = {Subscript[x, #1], #2} & @@@ vars;
Sum[Times @@ terms, Sequence @@ args]
```