Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.
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.

share|improve this question
2  
"2" is not the first common - "1" is –  volcano Apr 20 '13 at 9:22
3  
Really, is teaching a tag now? –  Martijn Pieters Apr 20 '13 at 9:41
1  
@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
3  
@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
2  
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

9 Answers 9

up vote 8 down vote accepted

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]
share|improve this answer
    
"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
2  
It's good now :) –  user2032433 Apr 20 '13 at 9:51
1  
@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
2  
@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
1  
@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
import threading, thread

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 = threading.Timer(20, thread.interrupt_main)   # 20 second time limit
            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)

share|improve this answer
    
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? –  1_CR 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

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.

share|improve this answer
    
Good stuff, thanks. –  georg Apr 20 '13 at 10:37
1  
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 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
    ret=-1  #return -1 if item is not found
    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     
share|improve this answer
    
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
1  
@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
1  
@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
1  
@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

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()
share|improve this answer

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)
share|improve this answer
1  
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
1  
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
1  
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
def first_common_element(x,y):
    common = set(x).intersection(set(y))
    if common:
        return x[min([x.index(i)for i in common])]
share|improve this answer

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
share|improve this answer

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.

share|improve this answer
1  
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

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.