Assuming I want have a numpy array of size `(n,m)` where `n` is very large, but with a lot of duplication, ie. `0:n1` are identical, `n1:n2` are identical etc. (with `n2%n1!=0`, ie not regular intervals). Is there a way to store only one set of values for each of the duplicates while having a view of the entire array?

example:

``````unique_values = np.array([[1,1,1], [2,2,2] ,[3,3,3]]) #these are the values i want to store in memory
index_mapping = np.array([0,0,1,1,1,2,2]) # a mapping between index of array above, with array below

unique_values_view = np.array([[1,1,1],[1,1,1],[2,2,2],[2,2,2],[2,2,2], [3,3,3],[3,3,3]]) #this is how I want the view to look like for broadcasting reasons
``````

I plan to multiply array(view) by some other array of size `(1,m)`, and take the dot product of this product:

``````other_array1 = np.arange(unique_values.shape[1]).reshape(1,-1) # (1,m)
other_array2 = 2*np.ones((unique_values.shape[1],1)) # (m,1)
output = np.dot(unique_values_view * other_array1, other_array2).squeeze()
``````

Output is a 1D array of length `n`.

• How do you plan to use the output? FYI : A view at the first stage, doesn't guarantee that there won't be forced-copy later on. – Divakar Jun 1 '18 at 7:56
• @Divakar True. I plan to multiply with another array of shape `(1,m)`, then storing the dot product with another array. The main consideration is fitting the array into memory. I could do the last step in chunks if it copying is enforced – M.T Jun 1 '18 at 8:07
• Or could add a bit more generic minimal sample, say `index_mapping` with bigger range of numbers and `unique_values` with random numbers? – Divakar Jun 4 '18 at 10:40
• By "identical" do you mean they are integers? Or just very close floats? (i.e can you do bitwise equvalence) – Daniel F Jun 5 '18 at 11:05
• @M.T Yakym Pirozhenko 's soln seem to work for the listed minimal case. But again, I can't see what would be the generic case. – Divakar Jun 5 '18 at 17:39

• do the indexing last
• multiply `other_array1` with `other_array2` first and then with `unique_values`

Let's apply these optimizations:

``````>>> output_pp = (unique_values @ (other_array1.ravel() * other_array2.ravel()))[index_mapping]

# check for correctness
>>> (output == output_pp).all()
True

# and compare it to @Yakym Pirozhenko's approach
>>> from timeit import timeit
>>> print("yp:", timeit("np.dot(unique_values * other_array1, other_array2).squeeze()[index_mapping]", globals=globals()))
yp: 3.9105667411349714
>>> print("pp:", timeit("(unique_values @ (other_array1.ravel() * other_array2.ravel()))[index_mapping]", globals=globals()))
pp: 2.2684884609188884
``````

These optimizations are easy to spot if we observe two things:

(1) if `A` is an `mxn`-matrix and `b` is an `n`-vector then

``````A * b == A @ diag(b)
A.T * b[:, None] == diag(b) @ A.T
``````

(2) if `A` is an`mxn`-matrix and `I` is a `k`-vector of integers from `range(m)` then

``````A[I] == onehot(I) @ A
``````

`onehot` can be defined as

``````def onehot(I, m, dtype=int):
out = np.zeros((I.size, m), dtype=dtype)
out[np.arange(I.size), I] = 1
return out
``````

Using these facts and abbreviating `uv`, `im`, `oa1` and `oa2` we can write

``````uv[im] * oa1 @ oa2 == onehot(im) @ uv @ diag(oa1) @ oa2
``````

The above optimizations are now simply a matter of choosing the best order for these matrix multiplications which is

``````onehot(im) @ (uv @ (diag(oa1) @ oa2))
``````

Using (1) and (2) backwards on this we obtain the optimized expression from the beginning of this post.

Based on your example, you can simply factor the index mapping through the computation to the very end:

``````output2 = np.dot(unique_values * other_array1, other_array2).squeeze()[index_mapping]

assert (output == output2).all()
``````