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I'm implementing a Matrix Product State class, which is some kind of special tensor decomposition scheme in python/numpy for fast algorithm prototyping.

I don't think that there already is such a thing out there, and I want to do it myself to get a proper understanding of the scheme.

What I want to have is that, if I store a given tensor T in this format as T_mps, I can access the reconstructed elements by T_mps[ [i0, i1, ..., iL] ]. This is achieved by the getitem(self, key) method and works fine.

Now I want to use numpy.allclose(T, mps_T) to see if my decomposition is correct.

But when I do this I get a type error for my own type:

TypeError: function not supported for these types, and can't coerce safely to supported types

I looked at the documentation of allclose and there it is said, that the function works for "array like" objects. Now, what is this "array like" concept and where can I find its specification ?

Maybe I'm better off, implementing my own allclose method ? But that would somewhat be reinventing the wheel, wouldn't it ?

Appreciate any help Thanks in advance

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up vote 3 down vote accepted

The term "arraylike" is used in the numpy documentation to mean "anything that can be passed to numpy.asarray() such that it returns an appropriate numpy.ndarray." Most sequences with proper __len__() and __getitem__() methods work okay. Note that the __getitem__(i) must be able to accept a single integer index in range(len(self)), not just a list of indices as you seem to indicate. The result from this __getitem__(i) must either be an atomic value that numpy knows about, like a float or an int, or be another sequence as above. Without more details about your Matrix Product State implementation, that's about all I can help.

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The __len__(i) getitem(i) approach doesn't really fit my datastructure, because each coefficient of the tensor is internally stored as a product of matrices (hence the name). I found another approach here: link There the array() function is used, but reconstructing the whole tensor as a numpy array defeats the whole purpose of the scheme. So I think I'll just shift the work to the testcases to sample some entries using the getitem([.....]) function. It is for debugging purposes only, anyway. –  Mischa Obrecht Mar 21 '12 at 16:03
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