Speed differences between intersection() and 'object for object in set if object in other_set'

Question

Which one of these is faster? Is one "better"? Basically I'll have two sets and I want to eventually get one match from between the two lists. So really I suppose the for loop is more like:

for object in set:
    if object in other_set:
        return object

Like I said - I only need one match, but I'm not sure how intersection() is handled, so I don't know if its any better. Also, if it helps, the other_set is a list near 100,000 components and the set is maybe a few hundred, max few thousand.

Answer 1

from timeit import timeit

setup = """
from random import sample, shuffle
a = range(100000)
b = sample(a, 1000)
a.reverse()
"""

forin = setup + """
def forin():
    # a = set(a)
    for obj in b:
        if obj in a:
            return obj
"""

setin = setup + """
def setin():
    # original method:
    # return tuple(set(a) & set(b))[0]
    # suggested in comment, doesn't change conclusion:
    return next(iter(set(a) & set(b)))
"""

print timeit("forin()", forin, number = 100)
print timeit("setin()", setin, number = 100)

Times:

>>>
0.0929054012768
0.637904308732
>>>
0.160845057616
1.08630760484
>>>
0.322059185123
1.10931801261
>>>
0.0758695262169
1.08920981403
>>>
0.247866360526
1.07724461708
>>>
0.301856152688
1.07903130641

Making them into sets in the setup and running 10000 runs instead of 100 yields

>>>
0.000413064976328
0.152831597075
>>>
0.00402408388788
1.49093627898
>>>
0.00394538156695
1.51841512101
>>>
0.00397715579584
1.52581949403
>>>
0.00421472926155
1.53156769646

So your version is much faster whether or not it makes sense to convert them to sets.

Answer 2

I realize this is a older post. But, I arrived here looking for performance speeds comparing using intersection vs in and thought it'd be worth adding more info. The answers above were great, but left me unclear as to the actual best path forward.

The "first result" solution doesn't solve for my use case specifically.

Instead, I wanted to know how the different implementations would perform, producing identical results sets, using discrete approaches. Not just the first single intersected value. As such, below I've included code to perform an evaluation of the options with a 1000 loop test. Contrary to what @agf posted, using sets is far faster when the desired output is a list of matches.

My results were:

runForin took 132851.600ms
runForinBlist took 37700.916ms
True
runForInListComp took 132783.147ms
True
runForinSet took 780.919ms
True
runSetIntersection took 760.980ms (WINNER)
True
runSetin took 771.921ms
True

Here's the code. Hope it helps someone. Note: I also evaluated the blist (http://stutzbachenterprises.com/blist/blist.html) library as it performs quite well in other use cases.

import time
from random import sample, shuffle
from blist import blist

a = range(100000)
aBlist = blist([i for i in a])

b = sample(a, 1000)
a.reverse()

def print_timing(func):
    def wrapper(*arg):
        t1 = time.time()
        res = func(*arg)
        t2 = time.time()
        print '%s took %0.3fms' % (func.func_name, (t2-t1)*1000.0)
        return res
    return wrapper


def forIn():
    ret = []
    for obj in b:
        if obj in a:
            ret.append(obj)
    return ret

def forInBlist():
    ret = []
    for obj in b:
        if obj in aBlist:
            ret.append(obj)
    return ret


def forInListComp():
    return [value for value in b if value in a] 


def forInSet():
    ret = []
    for obj in b:
        if obj in set(a):
            ret.append(obj)
    return ret


def setIntersection(): 
    return set(a).intersection(b) 


def setIn():
    return list(set(a) & set(b))


@print_timing
def runForIn(times):
    for i in range(times):
        ret = forIn()
    return ret
        
@print_timing
def runForInBlist(times):
    for i in range(times):
        ret = forInBlist()
    return ret

@print_timing
def runForInListComp(times):
    for i in range(times):
        ret = forInListComp()
    return ret

@print_timing
def runForInSet(times):
    for i in range(times):
        ret = forInSet()
    return ret

@print_timing
def runSetIntersection(times):
    for i in range(times):
        ret = setIntersection()
    return ret

@print_timing
def runSetIn(times):
    for i in range(times):
        ret = setIn()
    return ret

def checkResults(results):
    master = None
    for resultSet in results:
        if not master:
            master = sorted(list(resultSet))
            continue
        try:
            if master != sorted(list(resultSet)):
                return False, master, sorted(list(resultSet))
        except:
            print resultSet
            return False
    return True

iterations = 5
results = []
runForInResults = runForIn(iterations)
results.append(runForInResults)

runForInBlistResults = runForInBlist(iterations)
results.append(runForInBlistResults)
print checkResults(results)

runForInListCompResults = runForInListComp(iterations)
results.append(runForInListCompResults)
print checkResults(results)

runForInSetResults = runForInSet(iterations)
results.append(runForInSetResults)
print checkResults(results)

runSetIntersectionResults = runSetIntersection(iterations)
results.append(runSetIntersectionResults)
print checkResults(results)

runSetInResults = runSetIn(iterations)
results.append(runSetInResults)
print checkResults(results)

Answer 3

Your code is fine. Item lookup if object in other_set for sets is quite efficient.

Answer 4

I wrote a simple utility that checks if two sets have at least one element in common. I had the same optimization problem today and your post saved my day. This is just a way to thank you for pointing this out, hope this will help other people too :)

Notice. The utility does NOT return the first element in common but rather returns true if they have at least one element in common, false otherwise. Of course it can be easily hacked to meet your goal.

def nonEmptyIntersection(A, B):
    """
    Returns true if set A intersects set B.
    """
    smaller, bigger = A, B
    if len(B) < len(A):
        smaller, bigger = bigger, smaller
    for e in smaller:
        if e in bigger:
            return True
    return False