3

Consider the following:

tmp1 = ['a', 'b', 'c', 'd', 'e']
tmp2 = ['f', 'g', 'h', 'b', 'd']
tmp3 = ['b', 'i', 'j', 'k', 'l']
matr = np.array([tmp1, tmp2, tmp3])

matr

Yields a matrix:

array([['a', 'b', 'c', 'd', 'e'],
   ['f', 'g', 'h', 'b', 'd'],
   ['b', 'i', 'j', 'k', 'l']], 
  dtype='|S1')

Now, I want to know the sum of values in each row that intersects a vector. Say,

vec = ['a', 'c', 'f', 'b']
[sum([y in vec for y in row]) for row in matr]

Returns,

[3, 2, 1]

This is the desired output. The problem with it is that my 'matr' is actually ≈ 1000000 x 2200, and I have 6700 vectors to compare against. The solution I have here is far too slow to attempt.

How can I improve what I'm doing?

It's worth noting that the values inside of the matr come from a set of ~30000 values, and I have the full set. I've considered solutions where I make a dict of these 30000 values against each vector, and use the dict to convert to True/False throughout the matrix before just summing by row. I'm not sure if this will help.

  • 1
    Would all elements be single characters in the actual use case? – Divakar Mar 14 at 19:59
  • My fault in portraying it that way. Definitely not- closer to 12-13 characters. – John Rouhana Mar 14 at 20:03
  • Are those 6700 vectors of the same length? What's the typical length of those vectors? – Divakar Mar 15 at 6:35
  • Unfortunately they're not. Some are as small as ~50, but they're all between 10 and 1000. – John Rouhana Mar 15 at 15:06
2

For matr and vec as arrays, here's one with np.searchsorted -

def count_in_rowwise(matr,vec):
    sidx = vec.argsort()
    idx = np.searchsorted(vec,matr,sorter=sidx)
    idx[idx==len(vec)] = 0
    return (vec[sidx[idx]] == matr).sum(1)

With a comparatively smaller vec, we can pre-sort it and use, to give us an alternative one to compute the row-counts, like so -

def count_in_rowwise_v2(matr,vec,assume_sorted=False):
    if assume_sorted==1:
        sorted_vec = vec
    else:
        sorted_vec = np.sort(vec)
    idx = np.searchsorted(sorted_vec,matr)
    idx[idx==len(sorted_vec)] = 0
    return (sorted_vec[idx] == matr).sum(1)

The above solution(s) works on generic inputs(numbers or strings alike). To solve our specific case of strings, we could optimize it further by converting the strings to numbers by using np.unique and then re-using count_in_rowwise/count_in_rowwise_v2 and that will give us our second approach, like so -

u,ids = np.unique(matr, return_inverse=True)
out = count_in_rowwise(ids.reshape(matr.shape),ids[np.searchsorted(u,vec)])
  • While this seems interesting, I'm skeptical that it'll be faster... I'll benchmark tomorrow and get back to you for sure. – John Rouhana Mar 15 at 1:20
  • @JohnRouhana Any particular reason to be skeptical? And faster than the original loopy one? – Divakar Mar 15 at 4:06
  • It seemed like more steps, so I'm surprised that it's faster. I'm a bioinformatics guy, not pure computer science, so I don't really follow "why" it's so much faster than the other suggested methods. But it is. I ran benchmarks on a 1000x2200 matrix against 50 vectors. Going from my method to yours, the average time was brought down from ~4.9s/vector to ~0.088s/vector. That's approximately a 55x speedup- awesome. – John Rouhana Mar 15 at 19:24
  • 1
    @JohnRouhana Good to get the feedback! Well I was banking on searchsorted because it's pretty efficient, just needs a bit more work for its sorted requirement. Also, if you are operating on the same matr against those 6700 vectors, I would suggest going with the suggestion at the end : np.unique(.. to pre-compute u,ids once and re-use it on those 6700 vec's, to only use count_in_rowwise(ids.reshape(matr.shape),ids[np.searchsorted(u,vec)]) for each new vec. – Divakar Mar 15 at 19:30
  • Yes- this is precisely what I ended up doing. It still seems inconvenient to run against a 1,000,000x2200 matrix; by my projections, it would still take around 7 days to do this for all the vectors. That being said your solution has brought 100,000x2200 down to about 18 hours, which is totally acceptable. In most cases I won't need to run the full million. – John Rouhana Mar 15 at 20:05
2

You could use set intersection to speed things up a bit. Here's a comparison:

Your present solution with list comprehensions:

%%timeit
print([sum([y in vec for y in row]) for row in matr])
#Output
[3,2,1]
20 µs ± 1.9 µs per loop (mean ± std. dev. of 7 runs, 100000 loops each)

Proposed solution with set intersection in list comprehension:

%%timeit
print([len(set(row).intersection(vec)) for row in matr])
#Output:
[3,2,1]
17.8 µs ± 1.46 µs per loop (mean ± std. dev. of 7 runs, 100000 loops each)

And if the vec is also a set, we get even better efficiency:

%%timeit
vec = {'a', 'c', 'f', 'b'}
print([len(set(row).intersection(vec)) for row in matr])
#Output:
[3, 2, 1]
16.6 µs ± 1.99 µs per loop (mean ± std. dev. of 7 runs, 10000 loops each)
  • This solution becomes significantly more efficient than others if the matrix and vectors consist of sets in the first place. – Luke DeLuccia Mar 14 at 20:21
  • I can adjust the matrix and vectors to be sets instead of lists; all the values per row are unique, and the vector has unique values. This is promising. I'll benchmark with a larger matrix and vector tomorrow to see if this holds. – John Rouhana Mar 15 at 1:01
  • I ran my benchmarks using this method against my original method using a larger matrix of 1000x2200 and 50 vectors. In practice, I didn't see a substantial difference between having a list vec and a set vec; I typically saw a difference of .0001 seconds per vector, with the set vec being consistently faster. This method is a substantial improvement over what I had; I observed a 20-25 fold speedup at the matrix size above. Some of the other methods are benchmarking faster, though. – John Rouhana Mar 15 at 19:04
  • You may also consider adding threading or multiprocessing into the mix and perform benchmarking on all the methods. That should give you the best possible results. – amanb Mar 15 at 19:08
1

Here's a simple readable solution with np.isin() (docs):

np.sum(np.isin(matr, vec), axis=1)

As a bonus, you can just use np.isin() without the summing if you want to get which elements of the matrix are in the vectors:

>>> np.isin(matr, vec)
array([[ True,  True,  True, False, False],
       [ True, False, False,  True, False],
       [ True, False, False, False, False]])

which shows why summing along the rows produces the desired output.

  • This was going to be something I tried, but it turns out the system admin is running Numpy 1.11. This came out in 1.13. I'm going to bug him tomorrow to get us an update, and then I'll benchmark with the other solutions to see how we do. – John Rouhana Mar 15 at 1:22
  • 1
    @JohnRouhana ah, boo! If you are indeed restricted to solutions no greater than a specific numpy version, then I would suggest to edit OP and add a tag with that constraint (for future readers). – alkasm Mar 15 at 18:06
  • I definitely hear you. I'm glad this potential solution is here though, and I'm working on getting an update for numpy so I can see how this method pars up with the others. I'll update the OP if I'm not able to get a benchmark on this. – John Rouhana Mar 15 at 18:10
  • 1
    I got this to work; by my benchmarks, this is the second best method suggested. – John Rouhana Mar 15 at 19:19
1

Let's look at the speed of your current algorithm. According to the python wiki, checking if an item is in an array like y in vec is O(n), meaning worst case, it has to go through every element in vec. Since you're doing that check for every element of your matrix, your total number of operations is numRows * numCols * vecLen, which is O(n^3).

A faster way to do it is to construct a dictionary for vec to optimize lookups because dictionaries are O(1) instead of O(n), meaning they can do your check in 1 operation, no matter how long vec is:

vecDict = dict([(x, 1) for x in vec])

So, your new time complexity is (numRows * numCols) + vecLen, which is O(n^2), which I think is as fast as you can get for your data.

[sum([y in vecDict for y in row]) for row in matr]
  • 1
    Definitely valid point, and this is a solution I was considering before I saw the other solutions. While this is a substantial improvement over what I had originally (I observed a 10-15x speedup compared to my method when working with a matrix of 1000x2200), Divakar's and amanb's methods seem to be notably faster. – John Rouhana Mar 15 at 19:10
  • Hey, if it's faster, go for it. I'm not as up on python's numpy library. It could be that even though they're doing more operations, they're doing it natively, so it might be more optimized. – frodo2975 Mar 16 at 0:03

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