# Find two disjoint pairs of pairs that sum to the same vector

This is a follow-up to Find two pairs of pairs that sum to the same value .

I have random 2d arrays which I make using

``````import numpy as np
from itertools import combinations
n = 50
A = np.random.randint(2, size=(m,n))
``````

I would like to determine if the matrix has two disjoint pairs of pairs of columns which sum to the same column vector. I am looking for a fast method to do this. In the previous problem ((0,1), (0,2)) was acceptable as a pair of pairs of column indices but in this case it is not as 0 is in both pairs.

The accepted answer from the previous question is so cleverly optimised I can't see how to make this simple looking change unfortunately. (I am interested in columns rather than rows in this question but I can always just do A.transpose().)

Here is some code to show it testing all 4 by 4 arrays.

``````n = 4
nxn = np.arange(n*n).reshape(n, -1)
count = 0
for i in xrange(2**(n*n)):
A = (i >> nxn) %2
p = 1
for firstpair in combinations(range(n), 2):
for secondpair in combinations(range(n), 2):
if firstpair < secondpair and not set(firstpair) & set(secondpair):
if (np.array_equal(A[firstpair[0]] + A[firstpair[1]], A[secondpair[0]] + A[secondpair[1]] )):
if (p):
count +=1
p = 0
print count
``````

This should output 3136.

-
What's wrong with my solution? –  gg349 Jan 15 '14 at 19:47

Here is my solution, extended to do what I believe you want. It isn't entirely clear though; one may get an arbitrary number of row-pairs that sum to the same total; there may exist unique subsets of rows within them that sum to the same value. For instance:

Given this set of row-pairs that sum to the same total

``````[[19 19 30 30]
[11 16 11 16]]
``````

There exists a unique subset of these rows that may still be counted as valid; but should it?

``````[[19 30]
[16 11]]
``````

Anyway, I hope those details are easy to deal with, given the code below.

``````import numpy as np

n = 20
#also works for non-square A
A = np.random.randint(2, size=(n*6,n)).astype(np.int8)
##A = np.array( [[0, 0, 0], [1, 1, 1], [1, 1 ,1]], np.uint8)
##A = np.zeros((6,6))
#force the inclusion of some hits, to keep our algorithm on its toes
##A[0] = A[1]

def base_pack_lazy(a, base, dtype=np.uint64):
"""
pack the last axis of an array as minimal base representation
lazily yields packed columns of the original matrix
"""
a = np.ascontiguousarray( np.rollaxis(a, -1))
packing = int(np.dtype(dtype).itemsize * 8 / (float(base) / 2))
for columns in np.array_split(a, (len(a)-1)//packing+1):
R = np.zeros(a.shape[1:], dtype)
for col in columns:
R *= base
R += col
yield R

def unique_count(a):
"""returns counts of unique elements"""
unique, inverse = np.unique(a, return_inverse=True)
count = np.zeros(len(unique), np.int)
np.add.at(count, inverse, 1)        #note; this scatter operation requires numpy 1.8; use a sparse matrix otherwise!
return unique, count, inverse

def voidview(arr):
"""view the last axis of an array as a void object. can be used as a faster form of lexsort"""
return np.ascontiguousarray(arr).view(np.dtype((np.void, arr.dtype.itemsize * arr.shape[-1]))).reshape(arr.shape[:-1])

def has_identical_row_sums_lazy(A, combinations_index):
"""
compute the existence of combinations of rows summing to the same vector,
given an nxm matrix A and an index matrix specifying all combinations

naively, we need to compute the sum of each row combination at least once, giving n^3 computations
however, this isnt strictly required; we can lazily consider the columns, giving an early exit opportunity
all nicely vectorized of course
"""

multiplicity, combinations = combinations_index.shape
#list of indices into combinations_index, denoting possibly interacting combinations
active_combinations = np.arange(combinations, dtype=np.uint32)
#keep all packed columns; we might need them later
columns = []

for packed_column in base_pack_lazy(A, base=multiplicity+1):       #loop over packed cols
columns.append(packed_column)
#compute rowsums only for a fixed number of columns at a time.
#this is O(n^2) rather than O(n^3), and after considering the first column,
#we can typically already exclude almost all combinations
partial_rowsums = sum(packed_column[I[active_combinations]] for I in combinations_index)
#find duplicates in this column
unique, count, inverse = unique_count(partial_rowsums)
#prune those combinations which we can exclude as having different sums, based on columns inspected thus far
active_combinations = active_combinations[count[inverse] > 1]
#early exit; no pairs
if len(active_combinations)==0:
return False

"""
we now have a small set of relevant combinations, but we have lost the details of their particulars
to see which combinations of rows does sum to the same value, we do need to consider rows as a whole
we can simply apply the same mechanism, but for all columns at the same time,
but only for the selected subset of row combinations known to be relevant
"""
#construct full packed matrix
B = np.ascontiguousarray(np.vstack(columns).T)
#perform all relevant sums, over all columns
rowsums = sum(B[I[active_combinations]] for I in combinations_index)
#find the unique rowsums, by viewing rows as a void object
unique, count, inverse = unique_count(voidview(rowsums))
#if not, we did something wrong in deciding on active combinations
assert(np.all(count>1))

#loop over all sets of rows that sum to an identical unique value
for i in xrange(len(unique)):
#set of indexes into combinations_index;
#note that there may be more than two combinations that sum to the same value; we grab them all here
combinations_group = active_combinations[inverse==i]
#associated row-combinations
#array of shape=(mulitplicity,group_size)
row_combinations = combinations_index[:,combinations_group]

#if no duplicate rows involved, we have a match
if len(np.unique(row_combinations[:,[0,-1]])) == multiplicity*2:
print row_combinations
return True

#none of identical rowsums met uniqueness criteria
return False

def has_identical_triple_row_sums(A):
n = len(A)
idx = np.array( [(i,j,k)
for i in xrange(n)
for j in xrange(n)
for k in xrange(n)
if i<j and j<k], dtype=np.uint16)
idx = np.ascontiguousarray( idx.T)
return has_identical_row_sums_lazy(A, idx)

def has_identical_double_row_sums(A):
n = len(A)
idx = np.array(np.tril_indices(n,-1), dtype=np.int32)
return has_identical_row_sums_lazy(A, idx)

from time import clock
t = clock()
for i in xrange(1):
##    print has_identical_double_row_sums(A)
print has_identical_triple_row_sums(A)
print clock()-t
``````

Edit: code cleanup

-
In the case of a 2 by 4 array [[19 19 30 30], [11 16 11 16]] columns 0 and 3 have the same sum as columns 1 and 2. It doesn't make sense to consider rows for this problem as you need at least 4 for the definition of my problem to work. –  marshall Jan 15 '14 at 14:57
I don't understand your comment. Indeed, the sum over all indices in each of the 4 columns gives the same total. It would appear to me however, that the 2x2 subset [[19 30] [16 11]] meets the definition of combinations you are interested in, no? –  Eelco Hoogendoorn Jan 15 '14 at 15:07
Sorry there must be a misunderstanding. We need to find two disjoint pairs of pairs of columns. Say we find columns 0 and 1 in one set and 2 and 3 in the other. We then do the vector sum for columns 0 and 1 and get the vector [39,27] in this case. We then do the same for columns 2 and 3 and get [60,27] and find that [39,27] != [60,27]. However had we chosen columns 0 and 3 and columns 1 and 2 we would have got [49,27] for both vectors which is what we wanted to find. If there are only 2 columns we can't get two disjoint subsets of size 2 each. –  marshall Jan 15 '14 at 15:11
The tables I wrote down contains the indices into A. It is presumed that A has only 0 and 1 values in this code; so the vector sum can only be something like [2,1,0], not [39,27]. Indeed there seems to be a substantial misunderstanding between us. Have you tried running the code and looking at the output? –  Eelco Hoogendoorn Jan 15 '14 at 15:43
It should only have 0s and 1s as you say. I was just using the example you gave in your answer but I see I misunderstood completely what was in it! Let me run your code and take a look. –  marshall Jan 15 '14 at 15:46