For an array of size N, what is the number of comparisons required?
The optimal algorithm uses n+log n2 comparisons. Think of elements as competitors, and a tournament is going to rank them.
First, compare the elements, as in the tree

/ \
 
/ \ / \
x x x x
this takes n1 comparisons and each element is involved in comparison at most log n times. You will find the largest element as the winner.
The second largest element must have lost a match to the winner (he can't lose a match to a different element), so he's one of the log n elements the winner has played against. You can find which of them using log n  1 comparisons.
The optimality is proved via adversary argument. See https://math.stackexchange.com/questions/1601 or http://compgeom.cs.uiuc.edu/~jeffe/teaching/497/02selection.pdf or http://www.imada.sdu.dk/~jbj/DM19/lb06.pdf or https://www.utdallas.edu/~chandra/documents/6363/lbd.pdf

2@Jatin: No, it takes N+log N2 in total: N1 comparisons to find the maximum, and log N1 comparisons to find the largest element among the log N that lost to the maximal element. – sdcvvc Aug 18 '12 at 20:03

4Jatin: create a binary tree, and start filling it from the bottom. The leaves are elements of the array. Each internal vertex is maximum of its two children. The number of comparisons you need is the number of internal vertices, which is n1. Then, look at the "opponents" of the maximal element, those are the log N elements. – sdcvvc Aug 18 '12 at 20:40

1So this involves some space complexity and that answers everything to me :) – Sreekar Jul 31 '14 at 18:06

1@POOJA GUPTA: First, find the largest and 2nd largest element (as in my answer); that gives one logn term. The 3rd largest element must have lost either to the 1st or the 2nd one, so you need to check elements which lost the comparison to 1st greatest element (that's the second logn term) and to 2nd greatest element (that's the third logn term). – sdcvvc Oct 6 '14 at 17:25

3@Hengameh to be honest I don't see the reason for the 8. It takes (n + log n  2) comparisons to find largest and second largest element, call them L_1 and L_2; next, we find the largest element that lost to L_1, which is not L_2, there are log n1 candidates for this, which means log n2 comparisons, next, we find the largest element that lost to L_2, there are log n2 candidates, so log n3 comparisons, take the max of those two, this gives n+log n2 + log n  2 + log n  3 + 1=n+3 log n6. I might be missing something though, the logarithms should be under ceilings etc. – sdcvvc Jun 19 '15 at 20:59
You can find the second largest value with at most 2·(N1) comparisons and two variables that hold the largest and second largest value:
largest := numbers[0];
secondLargest := null
for i=1 to numbers.length1 do
number := numbers[i];
if number > largest then
secondLargest := largest;
largest := number;
else
if number > secondLargest then
secondLargest := number;
end;
end;
end;

2

3

1

1

1
Use Bubble sort or Selection sort algorithm which sorts the array in descending order. Don't sort the array completely. Just two passes. First pass gives the largest element and second pass will give you the second largest element.
No. of comparisons for first pass: n1
No. of comparisons for first pass: n2
Total no. of comparison for finding second largest: 2n3
May be you can generalize this algorithm. If you need the 3rd largest then you make 3 passes.
By above strategy you don't need any temporary variables as Bubble sort and Selection sort are in place sorting algorithms.

2

I am curious about the time complexity of this solution, as one loop will execute only two times. – Vikram Sep 22 '16 at 1:23

Here is some code that might not be optimal but at least actually finds the 2nd largest element:
if( val[ 0 ] > val[ 1 ] )
{
largest = val[ 0 ]
secondLargest = val[ 1 ];
}
else
{
largest = val[ 1 ]
secondLargest = val[ 0 ];
}
for( i = 2; i < N; ++i )
{
if( val[ i ] > secondLargest )
{
if( val[ i ] > largest )
{
secondLargest = largest;
largest = val[ i ];
}
else
{
secondLargest = val[ i ];
}
}
}
It needs at least N1 comparisons if the largest 2 elements are at the beginning of the array and at most 2N3 in the worst case (one of the first 2 elements is the smallest in the array).
case 1>9 8 7 6 5 4 3 2 1
case 2> 50 10 8 25 ........
case 3> 50 50 10 8 25.........
case 4> 50 50 10 8 50 25.......
public void second element()
{
int a[10],i,max1,max2;
max1=a[0],max2=a[1];
for(i=1;i<a.length();i++)
{
if(a[i]>max1)
{
max2=max1;
max1=a[i];
}
else if(a[i]>max2 &&a[i]!=max1)
max2=a[i];
else if(max1==max2)
max2=a[i];
}
}
Sorry, JS code...
Tested with the two inputs:
a = [55,11,66,77,72];
a = [ 0, 12, 13, 4, 5, 32, 8 ];
var first = Number.MIN_VALUE;
var second = Number.MIN_VALUE;
for (var i = 1, len = a.length; ++i < len;) {
var dist = a[i];
// get the largest 2
if (dist > first) {
second = first;
first = dist;
} else if (dist > second) { // && dist < first) { // this is actually not needed, I believe
second = dist;
}
}
console.log('largest, second largest',first,second);
largest, second largest 32 13
This should have a maximum of a.length*2 comparisons and only goes through the list once.
I know this is an old question, but here is my attempt at solving it, making use of the Tournament Algorithm. It is similar to the solution used by @sdcvvc , but I am using twodimensional array to store elements.
To make things work, there are two assumptions:
1) number of elements in the array is the power of 2
2) there are no duplicates in the array
The whole process consists of two steps:
1. building a 2D array by comparing two by two elements. First row in the 2D array is gonna be the entire input array. Next row contains results of the comparisons of the previous row. We continue comparisons on the newly built array and keep building the 2D array until an array of only one element (the largest one) is reached.
2. we have a 2Darray where last row contains only one element: the largest one. We continue going from the bottom to the top, in each array finding the element that was "beaten" by the largest and comparing it to the current "second largest" value. To find the element beaten by the largest, and to avoid O(n) comparisons, we must store the index of the largest element in the previous row. That way we can easily check the adjacent elements. At any level (above root level),the adjacent elements are obtained as:
leftAdjacent = rootIndex*2
rightAdjacent = rootIndex*2+1,
where rootIndex is index of the largest(root) element at the previous level.
I know the question asks for C++, but here is my attempt at solving it in Java. (I've used lists instead of arrays, to avoid messy changing of the array size and/or unnecessary array size calculations)
public static Integer findSecondLargest(List<Integer> list) {
if (list == null) {
return null;
}
if (list.size() == 1) {
return list.get(0);
}
List<List<Integer>> structure = buildUpStructure(list);
System.out.println(structure);
return secondLargest(structure);
}
public static List<List<Integer>> buildUpStructure(List<Integer> list) {
List<List<Integer>> newList = new ArrayList<List<Integer>>();
List<Integer> tmpList = new ArrayList<Integer>(list);
newList.add(tmpList);
int n = list.size();
while (n>1) {
tmpList = new ArrayList<Integer>();
for (int i = 0; i<n; i=i+2) {
Integer i1 = list.get(i);
Integer i2 = list.get(i+1);
tmpList.add(Math.max(i1, i2));
}
n/= 2;
newList.add(tmpList);
list = tmpList;
}
return newList;
}
public static Integer secondLargest(List<List<Integer>> structure) {
int n = structure.size();
int rootIndex = 0;
Integer largest = structure.get(n1).get(rootIndex);
List<Integer> tmpList = structure.get(n2);
Integer secondLargest = Integer.MIN_VALUE;
Integer leftAdjacent = 1;
Integer rightAdjacent = 1;
for (int i = n2; i>=0; i) {
rootIndex*=2;
tmpList = structure.get(i);
leftAdjacent = tmpList.get(rootIndex);
rightAdjacent = tmpList.get(rootIndex+1);
if (leftAdjacent.equals(largest)) {
if (rightAdjacent > secondLargest) {
secondLargest = rightAdjacent;
}
}
if (rightAdjacent.equals(largest)) {
if (leftAdjacent > secondLargest) {
secondLargest = leftAdjacent;
}
rootIndex=rootIndex+1;
}
}
return secondLargest;
}
Suppose provided array is inPutArray = [1,2,5,8,7,3] expected O/P > 7 (second largest)
take temp array
temp = [0,0], int dummmy=0;
for (no in inPutArray) {
if(temp[1]<no)
temp[1] = no
if(temp[0]<temp[1]){
dummmy = temp[0]
temp[0] = temp[1]
temp[1] = temp
}
}
print("Second largest no is %d",temp[1])
PHP version of the Gumbo algorithm: http://sandbox.onlinephpfunctions.com/code/51e1b05dac2e648fd13e0b60f44a2abe1e4a8689
$numbers = [10, 9, 2, 3, 4, 5, 6, 7];
$largest = $numbers[0];
$secondLargest = null;
for ($i=1; $i < count($numbers); $i++) {
$number = $numbers[$i];
if ($number > $largest) {
$secondLargest = $largest;
$largest = $number;
} else if ($number > $secondLargest) {
$secondLargest = $number;
}
}
echo "largest=$largest, secondLargest=$secondLargest";
Assuming space is irrelevant, this is the smallest I could get it. It requires 2*n comparisons in worst case, and n comparisons in best case:
arr = [ 0, 12, 13, 4, 5, 32, 8 ]
max = [ 1, 1 ]
for i in range(len(arr)):
if( arr[i] > max[0] ):
max.insert(0,arr[i])
elif( arr[i] > max[1] ):
max.insert(1,arr[i])
print max[1]
try this.
max1 = a[0].
max2.
for i = 0, until length:
if a[i] > max:
max2 = max1.
max1 = a[i].
#end IF
#end FOR
return min2.
it should work like a charm. low in complexity.
here is a java code.
int secondlLargestValue(int[] secondMax){
int max1 = secondMax[0]; // assign the first element of the array, no matter what, sorted or not.
int max2 = 0; // anything really work, but zero is just fundamental.
for(int n = 0; n < secondMax.length; n++){ // start at zero, end when larger than length, grow by 1.
if(secondMax[n] > max1){ // nth element of the array is larger than max1, if so.
max2 = max1; // largest in now second largest,
max1 = secondMax[n]; // and this nth element is now max.
}//end IF
}//end FOR
return max2;
}//end secondLargestValue()
Use counting sort and then find the second largest element, starting from index 0 towards the end. There should be at least 1 comparison, at most n1
(when there's only one element!).

This doesn't answer the question, which is about the number of comparisons. The question is for analysis of an algorithm, not just the algorithm itself. – eh9 Nov 9 '12 at 17:38
#include<stdio.h>
main()
{
int a[5] = {55,11,66,77,72};
int max,min,i;
int smax,smin;
max = min = a[0];
smax = smin = a[0];
for(i=0;i<=4;i++)
{
if(a[i]>max)
{
smax = max;
max = a[i];
}
if(max>a[i]&&smax<a[i])
{
smax = a[i];
}
}
printf("the first max element z %d\n",max);
printf("the second max element z %d\n",smax);
}
The accepted solution by sdcvvc in C++11.
#include <algorithm>
#include <iostream>
#include <vector>
#include <cassert>
#include <climits>
using std::vector;
using std::cout;
using std::endl;
using std::random_shuffle;
using std::min;
using std::max;
vector<int> create_tournament(const vector<int>& input) {
// make sure we have at least two elements, so the problem is interesting
if (input.size() <= 1) {
return input;
}
vector<int> result(2 * input.size()  1, 1);
int i = 0;
for (const auto& el : input) {
result[input.size()  1 + i] = el;
++i;
}
for (uint j = input.size() / 2; j > 0; j >>= 1) {
for (uint k = 0; k < 2 * j; k += 2) {
result[j  1 + k / 2] = min(result[2 * j  1 + k], result[2 * j + k]);
}
}
return result;
}
int second_smaller(const vector<int>& tournament) {
const auto& minimum = tournament[0];
int second = INT_MAX;
for (uint j = 0; j < tournament.size() / 2; ) {
if (tournament[2 * j + 1] == minimum) {
second = min(second, tournament[2 * j + 2]);
j = 2 * j + 1;
}
else {
second = min(second, tournament[2 * j + 1]);
j = 2 * j + 2;
}
}
return second;
}
void print_vector(const vector<int>& v) {
for (const auto& el : v) {
cout << el << " ";
}
cout << endl;
}
int main() {
vector<int> a;
for (int i = 1; i <= 2048; ++i)
a.push_back(i);
for (int i = 0; i < 1000; i++) {
random_shuffle(a.begin(), a.end());
const auto& v = create_tournament(a);
assert (second_smaller(v) == 2);
}
return 0;
}
I have gone through all the posts above but I am convinced that the implementation of the Tournament algorithm is the best approach. Let us consider the following algorithm posted by @Gumbo
largest := numbers[0];
secondLargest := null
for i=1 to numbers.length1 do
number := numbers[i];
if number > largest then
secondLargest := largest;
largest := number;
else
if number > secondLargest then
secondLargest := number;
end;
end;
end;
It is very good in case we are going to find the second largest number in an array. It has (2n1) number of comparisons. But what if you want to calculate the third largest number or some kth largest number. The above algorithm doesn't work. You got to another procedure.
So, I believe tournament algorithm approach is the best and here is the link for that.
The following solution would take 2(N1) comparisons:
arr #array with 'n' elements
first=arr[0]
second=999999 #large negative no
i=1
while i is less than length(arr):
if arr[i] greater than first:
second=first
first=arr[i]
else:
if arr[i] is greater than second and arr[i] less than first:
second=arr[i]
i=i+1
print second
It can be done in n + ceil(log n)  2 comparison.
Solution: it takes n1 comparisons to get minimum.
But to get minimum we will build a tournament in which each element will be grouped in pairs. like a tennis tournament and winner of any round will go forward.
Height of this tree will be log n since we half at each round.
Idea to get second minimum is that it will be beaten by minimum candidate in one of previous round. So, we need to find minimum in potential candidates (beaten by minimum).
Potential candidates will be log n = height of tree
So, no. of comparison to find minimum using tournament tree is n1 and for second minimum is log n 1 sums up = n + ceil(log n)  2
Here is C++ code
#include <iostream>
#include <cstdio>
#include <cstdlib>
#include <cmath>
#include <vector>
using namespace std;
typedef pair<int,int> ii;
bool isPowerOfTwo (int x)
{
/* First x in the below expression is for the case when x is 0 */
return x && (!(x&(x1)));
}
// modified
int log_2(unsigned int n) {
int bits = 0;
if (!isPowerOfTwo(n))
bits++;
if (n > 32767) {
n >>= 16;
bits += 16;
}
if (n > 127) {
n >>= 8;
bits += 8;
}
if (n > 7) {
n >>= 4;
bits += 4;
}
if (n > 1) {
n >>= 2;
bits += 2;
}
if (n > 0) {
bits++;
}
return bits;
}
int second_minima(int a[], unsigned int n) {
// build a tree of size of log2n in the form of 2d array
// 1st row represents all elements which fights for min
// candidate pairwise. winner of each pair moves to 2nd
// row and so on
int log_2n = log_2(n);
long comparison_count = 0;
// pair of ints : first element stores value and second
// stores index of its first row
ii **p = new ii*[log_2n];
int i, j, k;
for (i = 0, j = n; i < log_2n; i++) {
p[i] = new ii[j];
j = j&1 ? j/2+1 : j/2;
}
for (i = 0; i < n; i++)
p[0][i] = make_pair(a[i], i);
// find minima using pair wise fighting
for (i = 1, j = n; i < log_2n; i++) {
// for each pair
for (k = 0; k+1 < j; k += 2) {
// find its winner
if (++comparison_count && p[i1][k].first < p[i1][k+1].first) {
p[i][k/2].first = p[i1][k].first;
p[i][k/2].second = p[i1][k].second;
}
else {
p[i][k/2].first = p[i1][k+1].first;
p[i][k/2].second = p[i1][k+1].second;
}
}
// if no. of elements in row is odd the last element
// directly moves to next round (row)
if (j&1) {
p[i][j/2].first = p[i1][j1].first;
p[i][j/2].second = p[i1][j1].second;
}
j = j&1 ? j/2+1 : j/2;
}
int minima, second_minima;
int index;
minima = p[log_2n1][0].first;
// initialize second minima by its final (last 2nd row)
// potential candidate with which its final took place
second_minima = minima == p[log_2n2][0].first ? p[log_2n2][1].first : p[log_2n2][0].first;
// minima original index
index = p[log_2n1][0].second;
for (i = 0, j = n; i <= log_2n  3; i++) {
// if its last candidate in any round then there is
// no potential candidate
if (j&1 && index == j1) {
index /= 2;
j = j/2+1;
continue;
}
// if minima index is odd, then it fighted with its index  1
// else its index + 1
// this is a potential candidate for second minima, so check it
if (index&1) {
if (++comparison_count && second_minima > p[i][index1].first)
second_minima = p[i][index1].first;
}
else {
if (++comparison_count && second_minima > p[i][index+1].first)
second_minima = p[i][index+1].first;
}
index/=2;
j = j&1 ? j/2+1 : j/2;
}
printf("\n");
printf("Minimum : %d\n", minima);
printf("Second Minimum : %d\n", second_minima);
printf("comparison count : %ld\n", comparison_count);
printf("Least No. Of Comparisons (");
printf("n+ceil(log2_n)2) : %d\n", (int)(n+ceil(log(n)/log(2))2));
return 0;
}
int main()
{
unsigned int n;
scanf("%u", &n);
int a[n];
int i;
for (i = 0; i < n; i++)
scanf("%d", &a[i]);
second_minima(a,n);
return 0;
}
function findSecondLargeNumber(arr){
var fLargeNum = 0;
var sLargeNum = 0;
for(var i=0; i<arr.length; i++){
if(fLargeNum < arr[i]){
sLargeNum = fLargeNum;
fLargeNum = arr[i];
}else if(sLargeNum < arr[i]){
sLargeNum = arr[i];
}
}
return sLargeNum;
}
var myArray = [799, 85, 8, 1, 6, 4, 3, 2, 15, 0, 207, 75, 785, 122, 17];
Ref: http://www.ajaybadgujar.com/findingsecondlargestnumberfromarrayinjavascript/
A good way with O(1) time complexity would be to use a maxheap. Call the heapify twice and you have the answer.

1
int[] int_array = {4, 6, 2, 9, 1, 7, 4, 2, 9, 0, 3, 6, 1, 6, 8};
int largst=int_array[0];
int second=int_array[0];
for (int i=0; i<int_array.length; i++){
if(int_array[i]>largst) {
second=largst;
largst=int_array[i];
}
else if(int_array[i]>second && int_array[i]<largst) {
second=int_array[i];
}
}

everyone is missing that second condition in else part. Where you compare digit from array if it is greater than the second_largest and also less than the current largest_number. – Usman Oct 31 '17 at 6:32
I suppose, follow the "optimal algorithm uses n+log n2 comparisons" from above, the code that I came up with that doesn't use binary tree to store the value would be the following:
During each recursive call, the array size is cut in half.
So the number of comparison is:
1st iteration: n/2 comparisons
2nd iteration: n/4 comparisons
3rd iteration: n/8 comparisons
... Up to log n iterations?
Hence, total => n  1 comparisons?
function findSecondLargestInArray(array) {
let winner = [];
if (array.length === 2) {
if (array[0] < array[1]) {
return array[0];
} else {
return array[1];
}
}
for (let i = 1; i <= Math.floor(array.length / 2); i++) {
if (array[2 * i  1] > array[2 * i  2]) {
winner.push(array[2 * i  1]);
} else {
winner.push(array[2 * i  2]);
}
}
return findSecondLargestInArray(winner);
}
Assuming array contain 2^n number of numbers.
If there are 6 numbers, then 3 numbers will move to the next level, which is not right.
Need like 8 numbers => 4 number => 2 number => 1 number => 2^n number of number
class solution:
def SecondLargestNumber (self,l):
Largest = 0
secondLargest = 0
for i in l:
if i> Largest:
secondLargest = Largest
Largest = max(Largest, i)
return Largest, secondLargest

1The question was not about an implementation, but about the number of comparisons needed. This solution needs O(n) comparisons. Can there be a more efficient one? – sapanoia Nov 5 '17 at 19:26
package com.array.orderstatistics;
import java.util.Arrays;
import java.util.Collections;
public class SecondLargestElement {
/**
* Total Time Complexity will be n log n + O(1)
* @param str
*/
public static void main(String str[]) {
Integer[] integerArr = new Integer[] { 5, 1, 2, 6, 4 };
// Step1 : Time Complexity will be n log(n)
Arrays.sort(integerArr, Collections.reverseOrder());
// Step2 : Array.get Second largestElement
int secondLargestElement = integerArr[1];
System.out.println(secondLargestElement);
}
}

You forgot the bit where you count the number of comparisons. (Hint: there's quite a few hidden in the call to
Arrays.sort()
). – Toby Speight Feb 14 '18 at 11:57 
Thanks for the comments. I have corrected the code now. Arrays.sort(int[] a) in recent JDK is implemented with Dualpivot Quicksort algorithm which has O(n log n) average complexity and is performed inplace (e.g. requires no extra space). So the total time complexity of this program will be O(n log n) + O(1). – Yuvaraj Ram Feb 14 '18 at 12:35

Please add some explanation to your code! It will be much easier to understand when you do. – Arnav Borborah Feb 14 '18 at 15:17
Sort the array into ascending order then assign a variable to the (n1)th term.

2

Use brute force or tournament method, in brute force first comparison will take n1 and on deleting the largesT, second will take n2 = n1 + n2 = 2n3 comparison with O(1) and T(1). With tournament you need to make sure there are element with power of 2 else add additional numbers to array and comparison will reduce to n + logn  2 (logn creating tournament and n1 for finding the largest among who lost to largest in tournament) – atjoshi Nov 30 at 20:12
int
special case (or string at a real push), it's 0 comparisons... – Steve Jessop Sep 2 '10 at 16:30