Has anybody written an C++ STLcompliant algorithm that combines std::transform
and std::accumulate
into a single pass algorithm supporting both the unary and binary and perhaps even (nary!) variant, say std::transformed_accumulate
? I want this because I have found this pattern highly reusable in for example linear algebra for example in (l1)norm calculations. The l1norm calculates the sum of the absolute values of the elements.



Uhm... My bet is that you can do that by embedding your transformation into the binary predicate, tranform the element and accumulate after the transformation.
That functor would be equivalent to:
Of course this could be made generic, just pass the transformation functor to a generic base functor:
And you could also generalize on the type in the container... or even create a more generic transform_accumulator that takes both an accumulator and a transformation functors and applies them in order. Actual implementation left as an exercise for the reader. 


Although it may not exactly fit the original intent,
So, for your L1 you'd do something on this general order:
Only that doesn't quite work  right now, it's trying to pass
With this, your L1 normalization would look something like this:



If you want to use some parallelism, I made a quick version using OpenMP :
It is fast but there is certainly room for optimisation, especially around On a quick test with 1000000 elements array, and the computation iterated 1000 times to have a mean value, I made some comparisons. Version 1 :
score when compiled with:
Version 2 : This version is the most optimized for this computation I think. (It gives the best result).
Version 3 This version uses the MapReduce_n function template I shown earlier :



I am surprised noone said how to do this with Boost.Range:
where v is a Singe Pass Range (ie, any STL container). The abs overload has to be specified, otherwise this would be as elegant as Haskell. 

