# Numpy make the product between all elemens and then insert into a triangular 2d array

Suppose we got a 1D array below

``````arr = np.array([a,b,c])
``````

The first thing I need to do is the make the product of all of the elments, i.e

``````[ab,ac,bc]
``````

Then construct a 2d triangular array with this element

``````[
[a,ab,ac],
[0,b,bc],
[0,0,c]
]

``````

Create a diagonal with your 1-D array and fill the upper triangle of it with upper triangle of `outer`:

``````out = np.diag(arr)
#upper triangle indices
uidx = np.triu_indices(arr.size,k=1)
#replacing upper triangle with outer
out[uidx]=np.outer(arr,arr)[uidx]
``````
• This will be slower at scale, because you're allocating memory for an `(arr.size, arr.size)` array twice. If this calculation is being repeated on large arrays in a loop, this slowdown could become materially relevant. Jul 10, 2020 at 3:22
• @NickBecker I disagree. Computationally speaking this answer and the post below should be of the same order. Memory-wise it uses double. They both are essentially the same. It is up to the reader which one they find more readable. Jul 10, 2020 at 3:29
• Agreed, they are the same in terms of complexity. But the actual elapsed time is likely to be slower at scale/repeated due to the cost of the allocations. Timing a 20 iteration for loop with `arr = np.array(range(1,5000))`, I see a 30% difference in elapsed time. To be fair, this probably isn't relevant. Both are good answers :) Jul 10, 2020 at 3:39
• @NickBecker Thank you for the test run. When we look at improving performance, usually 30% will not be sth a user worries about (mostly in terms of x times is considered significant). However, of course the faster the better and your point is valid. Upvoting your answer. Jul 10, 2020 at 3:44
• Your answer is also good, as it's more clear in terms of readability. Upvoting as well Jul 10, 2020 at 3:50

One way to do this is to calculate the outer product of your 1d array and then use masking informed by the knowledge that you only want the upper triangle of the 2d triangular matrix.

``````import numpy as np

a = np.array([5,4,3])
n = len(a)

outer = np.outer(a, a)
outer[np.tril_indices(n)] = 0
outer[np.diag_indices(n)] = a

outer
array([[ 5, 20, 15],
[ 0,  4, 12],
[ 0,  0,  3]])
``````

We can use masking to achieve our desired result, like so -

``````def upper_outer(a):
out = a[:,None]*a
out[np.tri(len(a), k=-1, dtype=bool)] = 0
np.fill_diagonal(out,a)
return out
``````

Sample run -

``````In : a = np.array([3,6,2])

In : upper_outer(a)
Out:
array([[ 3, 18,  6],
[ 0,  6, 12],
[ 0,  0,  2]])
``````

### Benchmarking

Other approaches :

``````# @Nick Becker's soln
def tril_diag(a):
n = len(a)
outer = np.outer(a, a)
outer[np.tril_indices(n)] = 0
outer[np.diag_indices(n)] = a
return outer

# @Ehsan's soln
def triu_outer(arr):
out = np.diag(arr)
uidx = np.triu_indices(arr.size,k=1)
out[uidx]=np.outer(arr,arr)[uidx]
return out
``````

Using `benchit` package (few benchmarking tools packaged together; disclaimer: I am its author) to benchmark proposed solutions.

``````import benchit
in_ = [np.random.rand(n) for n in [10,100,200,500,1000,5000]]
funcs = [upper_outer, tril_diag, triu_outer]
t = benchit.timings(funcs, in_)
t.rank()
t.plot(logx=True, save='timings.png')
`````` For large datasets, we can also use `numexpr` to leverage multi-cores -

``````import numexpr as ne

def upper_outer_v2(a):
np.fill_diagonal(out,a)
return out
``````

New timings plot : • I like your answer and analysis. Upvoted. Interesting note on masks vs. indexing. Jul 10, 2020 at 6:55

There is a `blas` function for (almost) that:

``````# example
a = np.array([1.,2.,5.])

from scipy.linalg.blas import dsyr

# apply blas function; transpose since blas uses FORTRAN order
out = dsyr(1,a,1).T
# fix diagonal
out.reshape(-1)[::a.size+1] = a
out
# array([[ 1.,  2.,  5.],
#        [ 0.,  2., 10.],
#        [ 0.,  0.,  5.]])
``````

`benchit` (thanks @Divakar) • You got that working huh! Gotta lookup that new thing - `dsyr`. Jul 10, 2020 at 8:20
• @Divakar Yep, neat! Love the progress bars. Jul 10, 2020 at 8:25
• Lol, beats all (gotta be careful and say so far) :-) Jul 10, 2020 at 8:26
• The future is now :) Jul 10, 2020 at 15:00