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I am trying to speed up my code. The biggest problem is a few nested loops I have (they have to iterate over 25000 cells). However, when I try to get rid of these nested loops, I get a different result and I don't seem to get why.

This is one of the nested loop:

for i in range(N):
    for j in range(N):
        # value added in sector i (month k+1)
        VA[i,k+1]= VA[i,k+1] - IO[j,i]*(Produc[i,k+1]/Produc[i,0])

This is what I did to get rid of the inner loop:

for in range(N):
    VA[i,k+1]=VA[i,k+1] - np.sum(IO[:,i])*(Produc[i,k+1]/Produc[i,0])

Thank you for very much your help.

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use xrange instead of range (for Python version < 3), else it creates an array of size N every time –  Thomas Sep 20 '13 at 12:12
what is the size of IO ? you sum up from 0 to N-1 on j in the first case (inner loop) and from 0 to len(IO)-1 on j in the second case –  Thomas Sep 20 '13 at 12:14
@GrijeshChauhan: trying to make your single codebase futureproof by making it very inefficient on the interpreter you're already using seems like a Bad Idea. –  Wooble Sep 20 '13 at 12:16
@GrijeshChauhan, not exactly what I would call "more portable". The meaning of the code and the performance is very different. It just has the same end result in a lot of cases. 2to3 will do this transformation better. –  John La Rooy - AKA gnibbler Sep 20 '13 at 12:18
Can you give an example of two differing results? Is it possible that the difference is due to truncation of floating point values? –  bogatron Sep 20 '13 at 12:34

1 Answer 1

The problem is that assigning to VA constricts the type to VA.dtype, so you can lose accuracy if VA.dtype is less precise than the result from VA[i,k+1] - IO[j,i]*(Produc[i,k+1]/Produc[i,0]).

To keep this rounding you'd want:

for i in range(N):
    # value added in sector i (month k+1)
    VA[i,k+1] -= (IO[:,i]*(Produc[i,k+1]/Produc[i,0])).astype(VA.dtype).sum()

...assuming you're not more happy with the more accurate version!

Some more painstaking research has shown that if the subtractions take the data through 0, the behaviour isn't perfectly emulated. I wouldn't bother though, because emulating subtle bugs is a waste of time ;).

Note that if you're happy with

for in range(N):
    VA[i,k+1]=VA[i,k+1] - np.sum(IO[:,i])*(Produc[i,k+1]/Produc[i,0])

you can also do

VA[:,k+1] -= IO.sum(axis=0) * Produc[:,k+1] / Produc[:,0]

which I think is equivalent.

Note that this assumes that N is the perfect fit for a lot of these. It could be that VA[:N, :N] is a subset of VA, in which case that's the problem and you should crop everything to N within the calculations.

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Am I allowed to ask what the disagreement is? I have a sample data set where my answer works, so it's at least a reasonable guess. –  Veedrac Sep 20 '13 at 12:56
VA[:,k+1] -= IO.sum(axis=0) * Produc[:,k+1] / Produc[:,0] looks right to me. –  Greg Whittier Sep 20 '13 at 13:06
Your first statement is incorrect: you don't change the type by assigning to one item of an array. And you especially don't when you use -= or +=. –  Jaime Sep 20 '13 at 13:22
Ah, no, it's the type of the object you're adding, not of the array you're adding to. So [32] + 1.4 would become [33], and that's a rounding error that the original change didn't consider. It's an easy misunderstanding, I'll clear up the language. –  Veedrac Sep 20 '13 at 13:25
Even if the dtypes of all the arrays are identical, the results will likely be different due to truncation since you are now adding/subtracting values of different magnitudes. –  bogatron Sep 20 '13 at 13:42

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