This answer mentions the main points of an algorithm (called *DL* because it uses “divisor lists” ) and gives details via a program, called amodb.py.

Let B be the input array, containing N positive integers. Without much loss of generality, suppose `B[i] > K`

for all `i`

and that B is in ascending order. (Note that `x%B[i] < K`

if `B[i] < K`

; and where `B[i] = K`

, one can report pairs (B[i], B[j]) for all `j>i`

. If B is not sorted initially, charge a cost of `O(N log N)`

to sort it.)

In algorithm *DL* and program amodb.py, A is an array with K pre-subtracted from the input array elements. Ie, `A[i] = B[i] - K`

. Note that if `a%b == K`

, then for some `j`

we have `a = b*j + K`

or `a-K = b*j`

. That is, `a%b == K`

iff `a-K`

is a multiple of `b`

. Moreover, if `a-K = b*j`

and `p`

is any factor of `b`

, then `p`

is a factor of `a-K`

.

Let the prime numbers from 2 to 97 be called “small factors”. When N numbers are uniformly randomly selected from some interval [X,Y], on the order of N/ln(Y) of the numbers will have no small factors; a similar number will have a greatest small factor of 2; and declining proportions will have successively larger greatest small factors. For example, on the average about `N/97`

will be divisible by 97, about `N/89-N/(89*97)`

by 89 but not 97, etc. Generally, when members of B are random, lists of members with certain greatest small factors or with no small factors are sub-O(N/ln(Y)) in length.

Given a list Bd containing members of B divisible by largest small factor *p*, *DL* tests each element of Bd against elements of list Ad, those elements of A divisible by *p*. But given a list Bp for elements of B without small factors, *DL* tests each of Bp's elements against all elements of A. Example: If `N=25`

, `p=13`

, `Bd=[18967, 23231]`

, and `Ad=[12779, 162383]`

, then *DL* tests if any of `12779%18967, 162383%18967, 12779%23231, 162383%23231`

are zero. Note that it is possible to cut the number of tests in half in this example (and many others) by noticing `12779<18967`

, but amodb.py does not include that optimization.

*DL* makes `J`

different lists for `J`

different factors; in one version of amodb.py, `J=25`

and the factor set is primes less than 100. A larger value of `J`

would increase the `O(N*J)`

time to initialize divisor lists, but would slightly decrease the `O(N*len(Bp))`

time to process list Bp against elements of A. See results below. Time to process other lists is `O((N/logY)*(N/logY)*J)`

, which is in sharp contrast to the `O(n*sqrt(Y))`

complexity for a previous answer's method.

Shown next is output from two program runs. In each set, the first `Found`

line is from a naïve O(N*N) test, and the second is from *DL*. (Note, both *DL* and the naïve method would run faster if too-small A values were progressively removed.) The time ratio in the last line of the first test shows a disappointingly low speedup ratio of 3.9 for *DL* vs naïve method. For that run, `factors`

included only the 25 primes less than 100. For the second run, with better speedup of ~ 4.4, `factors`

included numbers 2 through 13 and primes up to 100.

```
$ python amodb.py
N: 10000 K: 59685 X: 100000 Y: 1000000
Found 208 matches in 21.854 seconds
Found 208 matches in 5.598 seconds
21.854 / 5.598 = 3.904
$ python amodb.py
N: 10000 K: 97881 X: 100000 Y: 1000000
Found 207 matches in 21.234 seconds
Found 207 matches in 4.851 seconds
21.234 / 4.851 = 4.377
```

Program amodb.py:

```
import random, time
factors = [2,3,4,5,6,7,8,9,10,11,12,13,17,19,23,29,31,37,41,43,47,53,59,61,67,71,73,79,83,89,97]
X, N = 100000, 10000
Y, K = 10*X, random.randint(X/2,X)
print "N: ", N, " K: ", K, "X: ", X, " Y: ", Y
B = sorted([random.randint(X,Y) for i in range(N)])
NP = len(factors); NP1 = NP+1
A, Az, Bz = [], [[] for i in range(NP1)], [[] for i in range(NP1)]
t0 = time.time()
for b in B:
a, aj, bj = b-K, -1, -1
A.append(a) # Add a to A
for j,p in enumerate(factors):
if a % p == 0:
aj = j
Az[aj].append(a)
if b % p == 0:
bj = j
Bz[bj].append(b)
Bp = Bz.pop() # Get not-factored B-values list into Bp
di = time.time() - t0; t0 = time.time()
c = 0
for a in A:
for b in B:
if a%b == 0:
c += 1
dq = round(time.time() - t0, 3); t0 = time.time()
c=0
for i,Bd in enumerate(Bz):
Ad = Az[i]
for b in Bd:
for ak in Ad:
if ak % b == 0:
c += 1
for b in Bp:
for ak in A:
if ak % b == 0:
c += 1
dr = round(di + time.time() - t0, 3)
print "Found", c, " matches in", dq, "seconds"
print "Found", c, " matches in", dr, "seconds"
print dq, "/", dr, "=", round(dq/dr, 3)
```

`A%B = K`

. The question that's being linked to is asking for an algorithm where`(A+B)%k = 0`

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