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# First common element from two lists

x = [8,2,3,4,5]
y = [6,3,7,2,1]

How to find out the first common element in two lists (in this case, "2") in a concise and elegant way? Any list can be empty or there can be no common elements - in this case None is fine.

I need this to show python to someone who is new to it, so the simpler the better.

UPD: the order is not important for my purposes, but let's assume I'm looking for the first element in x that also occurs in y.

-
"2" is not the first common - "1" is – volcano Apr 20 '13 at 9:22
Really, is teaching a tag now? – Martijn Pieters Apr 20 '13 at 9:41
@volcano why not? x,y are perfectly valid mathematical expressions, the same for i,j,k for iterators and iterators-like variables. Also when working with geometry a,b,c,d are quite common names for attributes in parametric equation. – Vyktor Apr 20 '13 at 9:46
@Vyktor Don't forget to mention k,v for iterations and z with x,y. Also, n often represents any natural number. – user2032433 Apr 20 '13 at 9:49
I'm not sure that the question is very well defined. Is the "first common element" always determined by the place in the x list? Could the answer be 3, since it appears earlier in the y list (or even because the sum of its indecies in the two list is the smallest)? – Blckknght Apr 20 '13 at 9:52

This should be straight forward and almost as effective as it gets (for more effective solution check Ashwini Chaudharys answer and for the most effective check jamylaks answer and comments):

result = None
# Go trough one array
for i in x:

# The element repeats in the other list...
if i in y:

# Store the result and break the loop
result = i
break

Or event more elegant would be to encapsulate the same functionality to functionusing PEP 8 like coding style conventions:

def get_first_common_element(x,y):
''' Fetches first element from x that is common for both lists
or return None if no such an element is found.
'''
for i in x:
if i in y:
return i

# In case no common element found, you could trigger Exception
# Or if no common element is _valid_ and common state of your application
# you could simply return None and test return value
# raise Exception('No common element found')
return None

And if you want all common elements you can do it simply like this:

>>> [i for i in x if i in y]
[1, 2, 3]
-
"Any list can be empty or there can be no common elements - in this case None is fine." I think you shouldn't raise an exception, just let the function return None. Also your indentation is wrong on the last 3 lines. – user2032433 Apr 20 '13 at 9:25
It's good now :) – user2032433 Apr 20 '13 at 9:51
@jamylak thanks you've convinced me and I've modified answer, but I don't believe that checking membership existence is O(1) (unless you've used some sort of index), I believe it's possible just in O(log(N)) – Vyktor Apr 20 '13 at 10:26
@Vyktor Can you please just read what a hash map is and stop arguing a completely wrong point... – jamylak Apr 20 '13 at 11:00
@Vyktor Just search the web, wikipedia, whatever, you don't have to be an expert just understand the concept if you want. btw I also posted timings in my answer for anyone else who doesn't believe me! – jamylak Apr 20 '13 at 12:59

A sort is not the fastest way of doing this, this gets it done in O(N) time with a set (hash map).

>>> x = [8,2,3,4,5]
>>> y = [6,3,7,2,1]
>>> set_y = set(y)
>>> next((a for a in x if a in set_y), None)
2

Or:

next(ifilter(set(y).__contains__, x), None)

This is what it does:

>>> def foo(x, y):
seen = set(y)
for item in x:
if item in seen:
return item
else:
return None

>>> foo(x, y)
2

To show the time differences between the different methods (naive approach, binary search an sets), here are some timings. I had to do this to disprove the suprising number of people that believed binary search was faster...:

from itertools import ifilter
from bisect import bisect_left

a = [1, 2, 3, 9, 1, 1] * 100000
b = [44, 11, 23, 9, 10, 99] * 10000

c = [1, 7, 2, 4, 1, 9, 9, 2] * 1000000 # repeats early
d = [7, 6, 11, 13, 19, 10, 19] * 1000000

e = range(50000)
f = range(40000, 90000) # repeats in the middle

g = [1] * 10000000 # no repeats at all
h = [2] * 10000000

from random import randrange
i = [randrange(10000000) for _ in xrange(5000000)] # some randoms
j = [randrange(10000000) for _ in xrange(5000000)]

def common_set(x, y, ifilter=ifilter, set=set, next=next):
return next(ifilter(set(y).__contains__, x), None)
pass

def common_b_sort(x, y, bisect=bisect_left, sorted=sorted, min=min, len=len):
sorted_y = sorted(y)
for a in x:
if a == sorted_y[min(bisect_left(sorted_y, a),len(sorted_y)-1)]:
return a
else:
return None

def common_naive(x, y):
for a in x:
for b in y:
if a == b: return a
else:
return None

from timeit import timeit
from itertools import repeat

print 'running tests - time limit of 20 seconds'

for x, y in [('a', 'b'), ('c', 'd'), ('e', 'f'), ('g', 'h'), ('i', 'j')]:
for func in ('common_set', 'common_b_sort', 'common_naive'):
try:
timer.start()
res = timeit(stmt="print '[', {0}({1}, {2}), ".format(func, x, y),
setup='from __main__ import common_set, common_b_sort, common_naive, {0}, {1}'.format(x, y),
number=1)
except:
res = "Too long!!"
finally:
print '] Function: {0}, {1}, {2}. Time: {3}'.format(func, x, y, res)
timer.cancel()

The test data was:

a = [1, 2, 3, 9, 1, 1] * 100000
b = [44, 11, 23, 9, 10, 99] * 10000

c = [1, 7, 2, 4, 1, 9, 9, 2] * 1000000 # repeats early
d = [7, 6, 11, 13, 19, 10, 19] * 1000000

e = range(50000)
f = range(40000, 90000) # repeats in the middle

g = [1] * 10000000 # no repeats at all
h = [2] * 10000000

from random import randrange
i = [randrange(10000000) for _ in xrange(5000000)] # some randoms
j = [randrange(10000000) for _ in xrange(5000000)]

Results:

running tests - time limit of 20 seconds
[ 9 ] Function: common_set, a, b. Time: 0.00569520707241
[ 9 ] Function: common_b_sort, a, b. Time: 0.0182240340602
[ 9 ] Function: common_naive, a, b. Time: 0.00978832505249
[ 7 ] Function: common_set, c, d. Time: 0.249175872911
[ 7 ] Function: common_b_sort, c, d. Time: 1.86735751332
[ 7 ] Function: common_naive, c, d. Time: 0.264309220865
[ 40000 ] Function: common_set, e, f. Time: 0.00966861710078
[ 40000 ] Function: common_b_sort, e, f. Time: 0.0505980508696
[ ] Function: common_naive, e, f. Time: Too long!!
[ None ] Function: common_set, g, h. Time: 1.11300018578
[ None ] Function: common_b_sort, g, h. Time: 14.9472068377
[ ] Function: common_naive, g, h. Time: Too long!!
[ 5411743 ] Function: common_set, i, j. Time: 1.88894859542
[ 5411743 ] Function: common_b_sort, i, j. Time: 6.28617268396
[ 5411743 ] Function: common_naive, i, j. Time: 1.11231867458

This gives you an idea of how it will scale for larger inputs, O(N) vs O(N log N) vs O(N^2)

-
IMO, this reads much better as a generator expression – Eric Apr 20 '13 at 10:28
Well, python is not the best language to learn functional programming. – georg Apr 20 '13 at 10:44
@Eric True, this was mostly for fun though... If I was really gonna do it I would just use a generator expression as you said. Update: I added the generator one now. – jamylak Apr 20 '13 at 10:46
+1. does the O(N log N) cost for binary search-based solution above account for the expense of sorting involved in getting to sorted_y? – iruvar Apr 20 '13 at 14:07
Yes, that's what I meant since the sorting sets the lower bound. – jamylak Apr 20 '13 at 14:15

One liner:

x = [8,2,3,4,5]
y = [6,3,7,2,1]

first = next((a for a in x if a in y), None)

Or more efficiently:

set_y = set(y)
first = next((a for a in x if a in set_y), None)

Or more efficiently but still in one line (don't do this):

first = next((lambda set_y: a for a in x if a in set_y)(set(y)), None)
-
Time complexity could be improved a lot by just using a set, which is not complicated compared to explaining next and generators. – Thijs van Dien Apr 20 '13 at 10:36
Yes, this is how things are done in python (assuming you know it :)) – georg Apr 20 '13 at 10:38
+1 But you should make set_y = set(y) and then it will be perfect – jamylak Apr 20 '13 at 10:47
@jamylak: Does next((a for a in x if a in set(y)), None) result in the set being constructed each time then? – Eric Apr 20 '13 at 11:00
Your second version: next(ifilter(set(y).__contains__, x), None). (Don't try this at home since you aren't supposed to use double under methods) – jamylak Apr 20 '13 at 11:02

Using a for loops with in will result in a O(N^2) complexity, but you can sort y here and use binary search to improve the time complexity to O(NlogN).

def binary_search(lis,num):
low=0
high=len(lis)-1
while low<=high:
mid=(low+high)//2
if num<lis[mid]:
high=mid-1
elif num>lis[mid]:
low=mid+1
else:
ret=mid
break

return ret

x = [8,2,3,4,5]
y = [6,3,7,2,1]
y.sort()

for z in x:
ind=binary_search(y,z)
if ind!=-1
print z
break

output: 2

Using the bisect module to perform the same thing as above:

import bisect

x = [8,2,3,4,5]
y = [6,3,7,2,1]
y.sort()

for z in x:
ind=bisect.bisect(y,z)-1  #or use `ind=min(bisect.bisect_left(y, z), len(y) - 1)`
if ind!=-1 and y[ind] ==z:
print z      #prints 2
break
-
However not very newbie friendly ;) – tyteen4a03 Apr 20 '13 at 9:37
Haha,+1, love your answer... (And removed note on effectiveness from mine)... But I'm afraid it's not newbie friendly... But still definitely worth mentioning for academical purposes. ;) – Vyktor Apr 20 '13 at 9:39
@GP89 binary search returns index and for z in x: if z in y is actually equivalent to two for loops. – Ashwini Chaudhary Apr 20 '13 at 9:43
@Vyktor BS is very famous, you can find tons of tutorials on it. Youtube - What is binary search, WikiPedia - Binary search Algo – Ashwini Chaudhary Apr 20 '13 at 10:10
@AshwiniChaudhary Thank you :D Was just gonna run timings, btw you do know there is a bisect module, it is very much neglected though it does what you want in one line – jamylak Apr 20 '13 at 11:12

I assume you want to teach this person Python, not just programming. Therefore I do not hesitate to use zip instead of ugly loop variables; it's a very useful part of Python and not hard to explain.

def first_common(x, y):
common = set(x) & set(y)
for current_x, current_y in zip(x, y):
if current_x in common:
return current_x
elif current_y in common:
return current_y

print first_common([8,2,3,4,5], [6,3,7,2,1])

If you really don't want to use zip, here's how to do it without:

def first_common2(x, y):
common = set(x) & set(y)
for i in xrange(min(len(x), len(y))):
if x[i] in common:
return x[i]
elif y[i] in common:
return y[i]

And for those interested, this is how it extends to any number of sequences:

def first_common3(*seqs):
common = set.intersection(*[set(seq) for seq in seqs])
for current_elements in zip(*seqs):
for element in current_elements:
if element in common:
return element

Finally, please note that, in contrast to some other solutions, this works as well if the first common element appears first in the second list.

I just noticed your update, which makes for an even simpler solution:

def first_common4(x, y):
ys = set(y) # We don't want this to be recreated for each element in x
for element in x:
if element in ys:
return element

The above is arguably more readable than the generator expression.

Too bad there is no built-in ordered set. It would have made for a more elegant solution.

-
Good stuff, thanks. – georg Apr 20 '13 at 10:37
izip_longest() could be replaced by the more common zip(): there is no need to keep searching in the longest sequence when the shortest one is exhausted, because any common element would have already been found in the shortest list. – EOL Apr 20 '13 at 12:13
@EOL thanks, you're right. – Thijs van Dien Apr 20 '13 at 13:58

Using for loops seems easiest to explain to someone new.

for number1 in x:
for number2 in y:
if number1 == number2:
print number1, number2
print x.index(number1), y.index(number2)
exit(0)
print "No common numbers found."

NB Not tested, just out of my head.

-
Actually, the second loop is not necessary - see the top answer. – georg Apr 20 '13 at 10:44
For functionality it's not, I thought it would help show how the program worked whilst teaching. But yes, I agree that this would be too long if used in an efficient program. – Pythonidae Apr 23 '13 at 16:58

This one uses sets. It returns the first common element or None if no common element.

def findcommon(x,y):
common = None
for i in range(0,max(len(x),len(y))):
common = set(x[0:i]).intersection(set(y[0:i]))
if common: break
return list(common)[0] if common else None
-
def first_common_element(x,y):
common = set(x).intersection(set(y))
if common:
return x[min([x.index(i)for i in common])]
-

Use set - this is the generic solution for arbitrary number of lists:

def first_common(*lsts):
common = reduce(lambda c, l: c & set(l), lsts[1:], set(lsts[0]))
if not common:
return None
firsts = [min(lst.index(el) for el in common) for lst in lsts]
index_in_list = min(firsts)
trgt_lst_index = firsts.index(index_in_list)
return lsts[trgt_lst_index][index_in_list]

An afterthought - not an effective solution, this one reduces redundant overhead

def first_common(*lsts):
common = reduce(lambda c, l: c & set(l), lsts[1:], set(lsts[0]))
if not common:
return None
for lsts_slice in itertools.izip_longest(*lsts):
slice_intersection = common.intersection(lsts_slice)
if slice_intersection:
return slice_intersection.pop()
-