I'm learning Python and the simple ways to handle lists is presented as an advantage. Sometimes it is, but look at this:

>>> numbers = [20,67,3,2.6,7,74,2.8,90.8,52.8,4,3,2,5,7]
>>> numbers.remove(max(numbers))
>>> max(numbers)

A very easy, quick way of obtaining the second largest number from a list. Except that the easy list processing helps write a program that runs through the list twice over, to find the largest and then the 2nd largest. It's also destructive - I need two copies of the data if I wanted to keep the original. We need:

>>> numbers = [20,67,3,2.6,7,74,2.8,90.8,52.8,4,3,2,5,7]
>>> if numbers[0]>numbers[1]):
...    m, m2 = numbers[0], numbers[1]
... else:
...    m, m2 = numbers[1], numbers[0]
>>> for x in numbers[2:]:
...    if x>m2:
...       if x>m:
...          m2, m = m, x
...       else:
...          m2 = x
>>> m2

Which runs through the list just once, but isn't terse and clear like the previous solution.

So: is there a way, in cases like this, to have both? The clarity of the first version, but the single run through of the second?

  • 1
    I think your second method (O(N)) is the best, because for large lists using a one-liner just because it is shorter is not a good idea. – Ashwini Chaudhary Apr 25 '13 at 22:29
  • 2
    Is running through the list twice really a problem? It's still O(N), and when you're dealing with cases where the algorithmic complexity is already good enough (or N is small), guesses about performance are almost useless. You need to write it multiple ways and timeit each one (and do so on all platforms/implementations you care about). And, unless this is a bottleneck, that isn't worth the effort. – abarnert Apr 25 '13 at 22:30
  • @abarnert, running twice through the list isn't a problem, but I'm trying to understand idiosyncracies of python before letting my students loose on it. I can see lots of cases where a student would take a list, run a transformation, another, another, and where the simple solution is the bad one. – boisvert Apr 25 '13 at 22:39
  • 2
    Now m2 will just be the largest if the first element is the largest. It also (I believe) fails to replace m2 when m2<x<m – Volatility Apr 25 '13 at 22:44
  • @boisvert: But the answer that's right for this toy example may not be—probably won't be—the answer that's right for a similar real-life case. For example, if you need to repeatedly get the top 2 as you continue to add to the list, you probably want to keep track of the top 2 as you go along and check each time you add, or keep the list continuously sorted (e.g., by using a tree-based collection like blist.sortedlist instead of a list). – abarnert Apr 25 '13 at 22:49

28 Answers 28


Since @OscarLopez and I have different opinions on what the second largest means, I'll post the code according to my interpretation and in line with the first algorithm provided by the questioner.

def second_largest(numbers):
    count = 0
    m1 = m2 = float('-inf')
    for x in numbers:
        count += 1
        if x > m2:
            if x >= m1:
                m1, m2 = x, m1            
                m2 = x
    return m2 if count >= 2 else None

(Note: Negative infinity is used here instead of None since None has different sorting behavior in Python 2 and 3 – see Python - Find second smallest number; a check for the number of elements in numbers makes sure that negative infinity won't be returned when the actual answer is undefined.)

If the maximum occurs multiple times, it may be the second largest as well. Another thing about this approach is that it works correctly if there are less than two elements; then there is no second largest.

Running the same tests:

=> 74
=> 1
=> 2
=> 10
=> 1
=> None
=> None


I restructured the conditionals to drastically improve performance; almost by a 100% in my testing on random numbers. The reason for this is that in the original version, the elif was always evaluated in the likely event that the next number is not the largest in the list. In other words, for practically every number in the list, two comparisons were made, whereas one comparison mostly suffices – if the number is not larger than the second largest, it's not larger than the largest either.

  • 1
    That is the functionality identical to finding max, removing, and finding max of the rest. – boisvert Apr 25 '13 at 23:23
  • @boisvert and what happens if there are several values with the same max? do yo remove all of them or just one? – Óscar López Apr 25 '13 at 23:27
  • 1
    @OscarLopez list.remove() removes only the first matching element found. – Thijs van Dien Apr 25 '13 at 23:28
  • 2
    You should not rely on Python 2 implementation details; the sort order of None is an arbitrary choice. Use float('inf') instead. – Martijn Pieters Nov 6 '14 at 12:48
  • 1
    @MartijnPieters The function should not return negative infinity (a number that could've been present) when the answer is actually undefined, though. Updated the answer to take that into account. – Thijs van Dien Nov 10 '14 at 21:00

You could use the heapq module:

>>> el = [20,67,3,2.6,7,74,2.8,90.8,52.8,4,3,2,5,7]
>>> import heapq
>>> heapq.nlargest(2, el)
[90.8, 74]

And go from there...

  • 17
    It is equivalent to : sorted(iterable,reverse=True)[:n], still NlogN – Ashwini Chaudhary Apr 25 '13 at 22:25
  • 1
    @AshwiniChaudhary functionally equivalent to that, yes; however because of the implementation it performs fewer comparisons so is more efficient than sorting and slicing – Jon Clements Apr 25 '13 at 22:28
  • 4
    @JonClements: But O(NlogN) is still nowhere near as good as O(N) for large N, and the OP already has an O(N) solution, which is what (I think) Ashwini is pointing out. – abarnert Apr 25 '13 at 22:31
  • 4
    From a very cursory test, with 64-bit CPython 3.3.0 on my Mac, the crossover is somewhere near N=1000000. Above that, the OP's original code is significantly faster; below it, the reverse. – abarnert Apr 25 '13 at 22:35
  • … and sorted does seem to be slower than heapq pretty much across the board, and they continue to diverge the larger N gets, so your point is valid as well. – abarnert Apr 25 '13 at 22:39

You could always use sorted

>>> sorted(numbers)[-2]
  • @ahairshi that depends on your definition of "second largest"; it will give 6. – Volatility Jun 11 '15 at 7:44
  • 6
    Posted answer below but it's basically this except: sorted(set(numbers))[-2] – Brent D. Jul 21 '15 at 23:04

Try the solution below, it's O(n) and it will store and return the second greatest number in the second variable. UPDATE: I've adjusted the code to work with Python 3, because now arithmetic comparisons against None are invalid.

Notice that if all elements in numbers are equal, or if numbers is empty or if it contains a single element, the variable second will end up with a value of None - this is correct, as in those cases there isn't a "second greatest" element.

Beware: this finds the "second maximum" value, if there's more than one value that is "first maximum", they will all be treated as the same maximum - in my definition, in a list such as this: [10, 7, 10] the correct answer is 7.

def second_largest(numbers):
    minimum = float('-inf')
    first, second = minimum, minimum
    for n in numbers:
        if n > first:
            first, second = n, first
        elif first > n > second:
            second = n
    return second if second != minimum else None

Here are some tests:

second_largest([20, 67, 3, 2.6, 7, 74, 2.8, 90.8, 52.8, 4, 3, 2, 5, 7])
=> 74
second_largest([1, 1, 1, 1, 1, 2])
=> 1
second_largest([2, 2, 2, 2, 2, 1])
=> 1
second_largest([10, 7, 10])
=> 7
second_largest( [1, 3, 10, 16])
=> 10
second_largest([1, 1, 1, 1, 1, 1])
=> None
=> None
=> None
  • 1
    It goes wrong if the maximum value occurs more than once. It should be if n >= first. Or do we consider duplicates as one? – Thijs van Dien Apr 25 '13 at 23:06
  • @ThijsvanDien I can't reproduce the error, can you provide a list to use as counterexample? and yes, I consider duplicates as one – Óscar López Apr 25 '13 at 23:08
  • [20,67,3,2.6,7,74,2.8,90.8,52.8,4,3,2,5,7,90.8], desired result: 90.8, actual result: 74. – Thijs van Dien Apr 25 '13 at 23:09
  • 1
    the second condition: elif first > n > second: second = n will never be met, there for should be removed – Roy learns to code Oct 27 '17 at 0:08
  • 1
    @NikhilTalreja thanks for reporting the bug! I've updated my code with the fix, adding your test case. The error started happening in Python 3, because now we can't do arithmetic comparisons against None. – Óscar López Dec 27 '19 at 14:17

Why to complicate the scenario? Its very simple and straight forward

  1. Convert list to set - removes duplicates
  2. Convert set to list again - which gives list in ascending order

Here is a code

mlist = [2, 3, 6, 6, 5]
mlist = list(set(mlist))
print mlist[-2]
  • 2
    The problem is the time taken for these operations (and, incidentally, duplicates wasn't my first problem). The sorting operation is O(n*log(n)), but finding the largest (without sorting) is linear ( O(n) ) since it takes one loop. A naive solution takes two loops: O(2n). A not-so-naive one should take one loop, seeking largest and second largest in a single pass. My real problem - not really answered here - is this: the single pass solutions are complex to read and write, in other words, python is not so good at making complex processing simple to express, as we like to say it is. – boisvert Nov 9 '16 at 10:54

You can find the 2nd largest by any of the following ways:

Option 1:

numbers = set(numbers)

Option 2:

  • 1
    Nice and simple solution. – Tony Ngo Dec 21 '20 at 10:28

The quickselect algorithm, O(n) cousin to quicksort, will do what you want. Quickselect has average performance O(n). Worst case performance is O(n^2) just like quicksort but that's rare, and modifications to quickselect reduce the worst case performance to O(n).

The idea of quickselect is to use the same pivot, lower, higher idea of quicksort, but to then ignore the lower part and to further order just the higher part.

  • 1
    @edward_doolittle, That's a very interesting idea. Part of my initial question was that the efficient solution wasn't 'neat'. An more general algorithm means that the not-so-neat elements of implementation can be factored away, at least in this case. – boisvert Nov 15 '15 at 21:49
  • 1
    This is used in numpy.partition (actually, it's the introselect algorithms, which upgrades quickselect). See f.ex. stackoverflow.com/a/43171040/1587329 – serv-inc Apr 2 '17 at 17:37

If you do not mind using numpy (import numpy as np):

np.partition(numbers, -2)[-2]

gives you the 2nd largest element of the list with a guaranteed worst-case O(n) running time.

The partition(a, kth) methods returns an array where the kth element is the same it would be in a sorted array, all elements before are smaller, and all behind are larger.


there are some good answers here for type([]), in case someone needed the same thing on a type({}) here it is,

def secondLargest(D):
    def second_largest(L):  
            raise Exception("Second_Of_One")
        KFL=None #KeyForLargest
        KFS=None #KeyForSecondLargest
        n = 0
        for k in L:
            if(KFL == None or k>=L[KFL]):
                KFS = KFL
                KFL = n
            elif(KFS == None or k>=L[KFS]):
                KFS = n
        return (KFS)
    KFL=None #KeyForLargest
    KFS=None #KeyForSecondLargest
        raise Exception("Second_Of_One")
            raise Exception("TypeError")
        for k in D:
            if(KFL == None or D[k]>=D[KFL]):
                KFS = KFL               
                KFL = k
            elif(KFS == None or D[k] >= D[KFS]):
                KFS = k

a = {'one':1 , 'two': 2 , 'thirty':30}
b = [30,1,2] 

Just for fun I tried to make it user friendly xD

>>> l = [19, 1, 2, 3, 4, 20, 20]
>>> sorted(set(l))[-2]
  • As with the other solution you commented on, this is not likely to be linear – Foon Jul 22 '15 at 2:28
  • 1
    Like several of the other solutions, calling sorted gives the result, but it doesn't do it efficiently. – boisvert Nov 15 '15 at 21:43

This can be done in [N + log(N) - 2] time, which is slightly better than the loose upper bound of 2N (which can be thought of O(N) too).

The trick is to use binary recursive calls and "tennis tournament" algorithm. The winner (the largest number) will emerge after all the 'matches' (takes N-1 time), but if we record the 'players' of all the matches, and among them, group all the players that the winner has beaten, the second largest number will be the largest number in this group, i.e. the 'losers' group.

The size of this 'losers' group is log(N), and again, we can revoke the binary recursive calls to find the largest among the losers, which will take [log(N) - 1] time. Actually, we can just linearly scan the losers group to get the answer too, the time budget is the same.

Below is a sample python code:

def largest(L):
    global paris
    if len(L) == 1:
        return L[0]
        left = largest(L[:len(L)//2])
        right = largest(L[len(L)//2:])
        pairs.append((left, right))
        return max(left, right)

def second_largest(L):
    global pairs
    biggest = largest(L)
    second_L = [min(item) for item in pairs if biggest in item]

    return biggest, largest(second_L)  

if __name__ == "__main__":
    pairs = []
    # test array
    L = [2,-2,10,5,4,3,1,2,90,-98,53,45,23,56,432]    

    if len(L) == 0:
        first, second = None, None
    elif len(L) == 1:
        first, second = L[0], None
        first, second = second_largest(L)

    print('The largest number is: ' + str(first))
    print('The 2nd largest number is: ' + str(second))

O(n): Time Complexity of a loop is considered as O(n) if the loop variables is incremented / decremented by a constant amount. For example following functions have O(n) time complexity.

 // Here c is a positive integer constant   
   for (int i = 1; i <= n; i += c) {  
        // some O(1) expressions

To find the second largest number i used the below method to find the largest number first and then search the list if thats in there or not

x = [1,2,3]
A = list(map(int, x))
y = max(A)
k1 = list()
for values in range(len(A)):
if y !=A[values]:

z = max(k1)
print z
  • Please add a description to explain your answer. – Murray Foxcroft Aug 2 '16 at 6:44

Objective: To find the second largest number from input.

Input : 5 2 3 6 6 5

Output: 5

*n = int(raw_input())
arr = map(int, raw_input().split())
print sorted(list(set(arr)))[-2]*
  • 2
    I see no difference from this answer – El Ruso Oct 24 '17 at 8:30
  • What value does this answer add relative to all the other answers posted here months and years ago? – Jean-François Corbett Oct 24 '17 at 8:46
    def SecondLargest(x):
        largest = max(x[0],x[1])
        largest2 = min(x[0],x[1])
        for item in x:
            if item > largest:
               largest2 = largest
               largest = item
            elif largest2 < item and item < largest:
               largest2 = item
        return largest2
list_nums = [1, 2, 6, 6, 5]
minimum = float('-inf')
max, min = minimum, minimum
for num in list_nums:
    if num > max:
        max, min = num, max
    elif max > num > min:
        min = num
print(min if min != minimum else None)



You can also try this:

>>> list=[20, 20, 19, 4, 3, 2, 1,100,200,100]
>>> sorted(set(list), key=int, reverse=True)[1]
  • How do you get sorted() to execute in O(n) time? It's usually O(n log n) – Toby Speight Apr 23 '18 at 12:41

A simple way :

arr = set(map(int, input().split()))
print (max(arr))

use defalut sort() method to get second largest number in the list. sort is in built method you do not need to import module for this.

lis = [11,52,63,85,14]
  • Thank you for this code snippet, which might provide some limited short-term help. A proper explanation would greatly improve its long-term value by showing why this is a good solution to the problem, and would make it more useful to future readers with other, similar questions. Please edit your answer to add some explanation, including the assumptions you've made. In particular, how do you get a sort() implementation that works in O(n)? – Toby Speight Apr 23 '18 at 12:38

Just to make the accepted answer more general, the following is the extension to get the kth largest value:

def kth_largest(numbers, k):
    largest_ladder = [float('-inf')] * k
    count = 0
    for x in numbers:
        count += 1
        ladder_pos = 1
        for v in largest_ladder:
            if x > v:
                ladder_pos += 1
        if ladder_pos > 1:
            largest_ladder = largest_ladder[1:ladder_pos] + [x] + largest_ladder[ladder_pos:]
    return largest_ladder[0] if count >= k else None
def secondlarget(passinput):
    passinputMax = max(passinput)  #find the maximum element from the array
    newpassinput = [i for i in passinput if i != passinputMax]  #Find the second largest element in the array
    #print (newpassinput)
    if len(newpassinput) > 0:
        return max(newpassinput) #return the second largest
    return 0
if __name__ == '__main__':
    n = int(input().strip())  # lets say 5
    passinput = list(map(int, input().rstrip().split())) # 1 2 2 3 3
    result = secondlarget(passinput) #2
    print (result) #2
if __name__ == '__main__':
    n = int(input())
    arr = list(map(float, input().split()))
    high = max(arr)
    secondhigh = min(arr)
    for x in arr:
        if x < high and x > secondhigh:
            secondhigh = x

The above code is when we are setting the elements value in the list as per user requirements. And below code is as per the question asked

numbers = [20, 67, 3 ,2.6, 7, 74, 2.8, 90.8, 52.8, 4, 3, 2, 5, 7]
#find the highest element in the list
high = max(numbers)
#find the lowest element in the list
secondhigh = min(numbers)
for x in numbers:
    find the second highest element in the list,
    it works even when there are duplicates highest element in the list.
    It runs through the entire list finding the next lowest element
    which is less then highest element but greater than lowest element in
    the list set initially. And assign that value to secondhigh variable, so 
    now this variable will have next lowest element in the list. And by end 
    of loop it will have the second highest element in the list  
    if (x<high and x>secondhigh):
  • 1
    Please add some explaining text to your answer, and explain how it relates to the examples of the question. You should probably also write code that treats the numbers variable defined in the question. – beruic Oct 2 '19 at 12:11
  • @beruic got it, please check – Nisrin Dhoondia Oct 8 '19 at 7:24
  • 1
    better, but this is not much faster than the users code, because you use both max and min. A quick optimization is that instead of spending O(n) time on finding the minimum, you could use secondhigh = float('-inf') instead. As long as the list contains more than one element, secondhigh will be replaced. If the list is to short, you should take that into consideration as well. – beruic Oct 8 '19 at 8:00

you have to compare in between new values, that's the trick, think always in the previous (the 2nd largest) should be between the max and the previous max before, that's the one!!!!

def secondLargest(lista):
    max_number   = 0
    prev_number  = 0

    for i in range(0, len(lista)):

        if lista[i] > max_number:
            prev_number = max_number
            max_number  = lista[i]
        elif lista[i] > prev_number and lista[i] < max_number:
            prev_number = lista[i]

    return prev_number

Most of previous answers are correct but here is another way !

Our strategy is to create a loop with two variables first_highest and second_highest. We loop through the numbers and if our current_value is greater than the first_highest then we set second_highest to be the same as first_highest and then the second_highest to be the current number. If our current number is greater than second_highest then we set second_highest to the same as current numberenter image description here

#!/usr/bin/env python3
import sys
def find_second_highest(numbers):

    min_integer = -sys.maxsize -1
    first_highest= second_highest = min_integer
    for current_number in numbers:
        if current_number == first_highest and min_integer != second_highest:
        elif current_number > first_highest:
            second_highest = first_highest
            first_highest = current_number
        elif current_number > second_highest:
            second_highest = current_number
    return second_highest

  • feel free to vote up 1+ if you like , always appreciate it @boisvert – grepit Nov 12 '18 at 17:58
  • This wont work in case of [2,3,6,6,5], output is 6 instead of 5 – Shivam Bharadwaj May 12 '20 at 12:52
  • @ Shivam Bharadwaj thanks for finding the edge case...I have revised it based on your feedback. – grepit May 13 '20 at 20:24

Best solution that my friend Dhanush Kumar came up with:

    def second_max(loop):
        glo_max = loop[0]
        sec_max = float("-inf")
        for i in loop:
            if i > glo_max:
                sec_max = glo_max
            elif sec_max < i < glo_max:
                sec_max = i
        return sec_max
    assert second_max([-1,-3,-4,-5,-7])==-3
    assert second_max([5,3,5,1,2]) == 3
    assert second_max([1,2,3,4,5,7]) ==5
    assert second_max([-3,1,2,5,-2,3,4]) == 4
    assert second_max([-3,-2,5,-1,0]) == 0
    assert second_max([0,0,0,1,0]) == 0

Below code will find the max and the second max numbers without the use of max function. I assume that the input will be numeric and the numbers are separated by single space.

myList = input().split()
myList = list(map(eval,myList))

m1 = myList[0]
m2 = myList[0]

for x in myList:
    if x > m1:
        m2 = m1
        m1 = x
    elif x > m2:
        m2 = x

print ('Max Number: ',m1)
print ('2nd Max Number: ',m2)

Here I tried to come up with an answer. 2nd(Second) maximum element in a list using single loop and without using any inbuilt function.

def secondLargest(lst):
    mx = 0
    num = 0
    sec = 0
    for i in lst:
        if i > mx:
            sec = mx
            mx = i
            if i > num and num >= sec:
                sec = i
            num = i
    return sec
n=input("Enter a list:")
print n[l-1]
  • 4
    Definitely not linear time. – 4ae1e1 Nov 15 '15 at 5:05

Max out the value by comparing each one to the max_item. In the first if, every time the value of max_item changes it gives its previous value to second_max. To tightly couple the two second if ensures the boundary

def secondmax(self, list):
    max_item = list[0]
    second_max = list[1]
    for item in list:
        if item > max_item:
            second_max =  max_item
            max_item = item
        if max_item < second_max:
            max_item = second_max
    return second_max

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