Suppose you have a python algorithm like this:

```
import math
import random
def find_duplicate(arr, gap):
cost, reps = 0, 0
while True:
indexes = sorted((random.randint(0,len(arr)-i-1) for i in xrange(gap)), reverse=True)
selection = [arr.pop(i) for i in indexes]
selection_set = set(selection)
cost += len(selection)
reps += 1
if len(selection) > len(selection_set):
return cost, reps
```

The idea is that **arr** is your set of values and **gap** is the log base-2 of the size. Each time you select **gap** elements and see if there are duplicated values. If so, return your cost (in count of elements examined) and the number of iterations (where you examine log2(size) elements per iteration). Otherwise, look at another **gap**-sized set.

The problem with benchmarking this algorithm is that the creation of the data each time through the loop and alteration of the data is expensive, assuming a large amount of data. (Initially, I was doing 1 000 000 elements with 10 000 000 iterations.)

So let's reduce to an equivalent problem. The data is passed in as n/2 unique elements and n/2 repeated elements. The algorithm picks the random indexes of log2(n) elements and checks for duplicates. Now we don't even have to create the data and to remove elements examined: **we can just check if we have two or more indexes over the halfway point**. Select **gap** indexes, check for 2 or more over the halfway point: return if found, otherwise repeat.

```
import math
import random
def find_duplicate(total, half, gap):
cost, reps = 0, 0
while True:
indexes = [random.randint(0,total-i-1) for i in range(gap)]
cost += gap
reps += 1
above_half = [i for i in indexes if i >= half]
if len(above_half) >= 2:
return cost, reps
else:
total -= len(indexes)
half -= (len(indexes) - len(above_half))
```

Now drive the code like this:

```
if __name__ == '__main__':
import sys
import collections
import datetime
for total in [2**i for i in range(5, 21)]:
half = total // 2
gap = int(math.ceil(math.log10(total) / math.log10(2)))
d = collections.defaultdict(int)
total_cost, total_reps = 0, 1000*1000*10
s = datetime.datetime.now()
for _ in xrange(total_reps):
cost, reps = find_duplicate(total, half, gap)
d[reps] += 1
total_cost += cost
e = datetime.datetime.now()
print "Elapsed: ", (e - s)
print "%d elements" % total
print "block size %d (log of # elements)" % gap
for k in sorted(d.keys()):
print k, d[k]
average_cost = float(total_cost) / float(total_reps)
average_logs = average_cost / gap
print "Total cost: ", total_cost
print "Average cost in accesses: %f" % average_cost
print "Average cost in logs: %f" % average_logs
print
```

If you try this test, you'll find that the number of times the algorithm has to do multiple selections declines with the number of elements in the data. That is, **your average cost in logs asymptotically approaches 1**.

```
elements accesses log-accesses
32 6.362279 1.272456
64 6.858437 1.143073
128 7.524225 1.074889
256 8.317139 1.039642
512 9.189112 1.021012
1024 10.112867 1.011287
2048 11.066819 1.006075
4096 12.038827 1.003236
8192 13.022343 1.001719
16384 14.013163 1.000940
32768 15.007320 1.000488
65536 16.004213 1.000263
131072 17.002441 1.000144
262144 18.001348 1.000075
524288 19.000775 1.000041
1048576 20.000428 1.000021
```

Now is this an argument for the ideal algorithm being log2(n) **in the average case**? Perhaps. It certainly is not so in the worst case.

Also, you don't have to pick log2(n) elements at once. You can pick 2 and check for equality (but in the degenerate case, you will not find the duplication at all), or check any other number greater for duplication. At this point, all the algorithms that select elements and check for duplication are identical, varying only in how many they pick and how they identify duplication.