New answers tagged dot-product
I finally used the 'Cosine' distance metric of scikit-learn and its pairwise_distances functions which support sparse matrices and is highly parallelised. sklearn.metrics.pairwise.pairwise_distances(X, Y=None, metric='euclidean', n_jobs=1, **kwds) I could also divide A into n horizontal parts and use the parallel python package to run multiple ...
Your average method changes the value of a, to make it the same as the average point. So your cube isn't a cube, after you've called average - three of the faces have rotated into new positions. So whatever happens in the loop over collider is wrong.
The problem is not in the assembly code, but in main. int16_t *dot; This is an uninitialized pointer; it could point anywhere, which typically means to a random address that is not yours. Hence the segfault here: movq [ecx], mm4 The quickest solution is to replace int16_t *dot; by: int16_t dot; Though I would be more inclined to make ...
My favorite Pythonic dot product is: sum([i*j for (i, j) in zip(list1, list2)]) So for your case we could do: sum([i*j for (i, j) in zip([K for K in A], B)])
I need to know for my application if two segments are near-collinear. It's about extracting lines from a laser scan. I will explain the solution I am using. It works pretty well. (Excuse my English!) I think the conditions that KeithS proposes for near-collinearity are wrong. They are near-colinear if they share one point and are near-parallel. If ...
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