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I may be misunderstanding how broadcasting works in Python, but I am still running into errors.

scipy offers a number of "special functions" which take in two arguments, in particular the eval_XX(n, x[,out]) functions. See http://docs.scipy.org/doc/scipy/reference/special.html

My program uses many orthogonal polynomials, so I must evaluate these polynomials at distinct points. Let's take the concrete example scipy.special.eval_hermite(n, x, out=None).

I would like the x argument to be a matrix shape (50, 50). Then, I would like to evaluate each entry of this matrix at a number of points. Let's define n to be an a numpy array narr = np.arange(10) (where we have imported numpy as np, i.e. import numpy as np).

So, calling

scipy.special.eval_hermite(narr, matrix)

should return Hermitian polynomials H_0(matrix), H_1(matrix), H_2(matrix), etc. Each H_X(matrix) is of the shape (50,50), the shape of the original input matrix.

Then, I would like to sum these values. So, I call

matrix1 = np.sum( [scipy.eval_hermite(narr, matrix)], axis=0 )

but I get a broadcasting error!

ValueError: operands could not be broadcast together with shapes (10,) (50,50)

I can solve this with a for loop, i.e.

matrix2 = np.sum( [scipy.eval_hermite(i, matrix) for i in narr], axis=0)

This gives me the correct answer, and the output matrix2.shape = (50,50). But using this for loop slows down my code, big time. Remember, we are working with entries of matrices.

Is there a way to do this without a for loop?

  • narr isn't that big - just 10 entries - so why is this so slow? The list comprehension should just produce a list of 10 arrays, which np.sum should sum pretty quickly. – nneonneo May 6 '15 at 16:54
  • @nneonneo I am using this for an easy example. Actually, some matrices are shape (1000, 1000). – ShanZhengYang May 6 '15 at 16:55
  • It shouldn't matter unless your narr is huge, and I'm not sure why it would be - it's just the order of the polynomial, and you shouldn't be needing 1000-degree Hermite polynomials. – nneonneo May 6 '15 at 16:57
  • @nneonneo At most the narr is of length 100. So yes, it does slow down the code. A lot. – ShanZhengYang May 6 '15 at 17:02
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eval_hermite broadcasts n with x, then evaluates Hn(x) at each point. Thus, the output shape will be the result of broadcasting n with x. So, if you want to make this work, you'll have to make n and x have compatible shapes:

import scipy.special as ss
import numpy as np
matrix = np.ones([100,100]) # example
narr = np.arange(10) # example
ss.eval_hermite(narr[:,None,None], matrix).shape # => (10, 100, 100)

But note that this might actually be faster:

out = np.zeros_like(matrix)
for n in narr:
    out += ss.eval_hermite(n, matrix)

In testing, it appears to be between 5-10% faster than np.sum(...) of above.

  • Broadcasting rules when applied to multiplying arrays in a summation gets confusing for me. If I understand correctly, the shape of ss.eval_hermite is now (10,100,100). Isn't this a different result than my operation above? (In that example, it would be matrix2.shape=(50,50, but here it would be shape=(100,100)) Further question: what is I need to do another summation with ss.eval_hermite(narr[:,None,None], matrix), but this time my array of ints for n is 20 values. I'm going to run into the same problem, aren't I? – ShanZhengYang May 6 '15 at 23:30
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    The sizes of matrix and narr are just examples above. You can define matrix and narr any way you want (provided they are 2D and 1D respectively) and the ss.eval_hermite(narr[:,None,None], matrix).shape will behave correctly. The technical explanation is that the [:,None,None] adds two extra size-1 dimensions to narr, making it broadcast-compatible with matrix (by having the last dimensions of both be compatible). – nneonneo May 7 '15 at 1:56
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The documentation for these functions is skimpy, and a lot of the code is compiled, so this is just based on experimentation:

special.eval_hermite(n, x, out=None)

n apparently is a scalar or array of integers. x can be an array of floats.

special.eval_hermite(np.ones(5,int)[:,None],np.ones(6)) gives me a (5,6) result. This is the same shape as what I'd get from np.ones(5,int)[:,None] * np.ones(6).

The np.ones(5,int)[:,None] is a (5,1) array, np.ones(6) a (6,), which for this purpose is equivalent of (1,6). Both can be expanded to (5,6).

So as best I can tell, broadcasting rules in these special functions is the same as for operators like *.


Since special.eval_hermite(nar[:,None,None], x) produces a (10,50,50), you just apply sum to axis 0 of that to produce the (50,50).

special.eval_hermite(nar[:,Nar,Nar], x).sum(axis=0)

Like I wrote before, the same broadcasting (and summing) rules apply for this hermite as they do for a basic operation like *.

  • Please see my comment to @nneonneo below. – ShanZhengYang May 6 '15 at 23:52
  • Just apply sum(axis=0) to that (N, M,M) result. Same as broadcasting and summing with *. – hpaulj May 7 '15 at 2:00

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