# How to find max. and min. in array using minimum comparisons?

This is a interview question: given an array of integers find the max. and min. using minimum comparisons.

Obviously, I can loop over the array twice and use `~2n` comparisons in the worst case but I would like to do better.

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Well, I can imagine algorithms that need no comparisons at all (e.g. apply counting sort, then pick the first and last item). But I don't suppose that's the point. – delnan Nov 24 '12 at 19:10
Just out of curiosity, Which companies ask such questions? I have been interviewed by many companies but I have never seen any question like this. – AlienOnEarth Oct 7 '15 at 7:10
@AlienOnEarth It was an Israeli startup. – Michael Oct 7 '15 at 8:12

``````1. Pick 2 elements(a, b), compare them. (say a > b)
2. Update min by comparing (min, b)
3. Update max by comparing (max, a)
``````

This way you would do 3 comparisons for 2 elements, amounting to `3N/2` total comparisons for `N` elements.

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Should it not be `3N/2 - 2` since we do not need to update min or max in the very first step? – Tom May 9 '15 at 19:22

Trying to improve on the answer by srbh.kmr. Say we have the sequence:

``````A = [a1, a2, a3, a4, a5]
``````

Compare `a1` & `a2` and calculate `min12`, `max12`:

``````if (a1 > a2)
min12 = a2
max12 = a1
else
min12 = a1
max12 = a2
``````

Similarly calculate `min34`, `max34`. Since `a5` is alone, keep it as it is...

Now compare `min12` & `min34` and calculate `min14`, similarly calculate `max14`. Finally compare `min14` & `a5` to calculate `min15`. Similarly calculate `max15`.

Altogether it's only 6 comparisons!

This solution can be extended to an array of arbitrary length. Probably can be implemented by a similar approach to merge-sort (break the array in half and calculate `min` `max` for each half).

UPDATE: Here's the recursive code in C:

``````#include <stdio.h>

void minmax (int* a, int i, int j, int* min, int* max) {
int lmin, lmax, rmin, rmax, mid;
if (i == j) {
*min = a[i];
*max = a[j];
} else if (j == i + 1) {
if (a[i] > a[j]) {
*min = a[j];
*max = a[i];
} else {
*min = a[i];
*max = a[j];
}
} else {
mid = (i + j) / 2;
minmax(a, i, mid, &lmin, &lmax);
minmax(a, mid + 1, j, &rmin, &rmax);
*min = (lmin > rmin) ? rmin : lmin;
*max = (lmax > rmax) ? lmax : rmax;
}
}

void main () {
int a [] = {3, 4, 2, 6, 8, 1, 9, 12, 15, 11};
int min, max;
minmax (a, 0, 9, &min, &max);
printf ("Min : %d, Max: %d\n", min, max);
}
``````

Now I cannot make out the exact number of comparisons in terms of `N` (the number of elements in the array). But it's hard to see how one can go below this many comparisons.

UPDATE: We can work out the number of comparisons like below:

At the bottom of this tree of computations, we form pairs of integers from the original array. So we have `N / 2` leaf nodes. For each of these leaf nodes we do exactly 1 comparison.

By referring to the properties of a perfect-binary-tree, we have:

``````leaf nodes (L) = N / 2 // known
total nodes (n) = 2L - 1 = N - 1
internal nodes = n - L = N / 2 - 1
``````

For each internal node we do 2 comparisons. Therefore, we have `N - 2` comparisons. Along with the `N / 2` comparisons at the leaf nodes, we have `(3N / 2) - 2` total comparisons.

So, may be this is the solution srbh.kmr implied in his answer.

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It can be implemented with a divide-and-conquer strategy. – Matthew Hall Nov 24 '12 at 23:14
+1 Nice analysis. Your tournament-like approach is I think just another way of looking at it. You could do it linearly also, just keep on comparing next 2 unprocessed pairs (a, b) and update the min, max as I explained in my answer. I think in both approaches comparisons made would be `3N/2-2` or `3N/2-3/2` depending on odd/even N. You could save extra recursion space if you go for a linear scan though ;) – srbhkmr Nov 25 '12 at 4:04
See Knuth Volume 3, chapter 5.3.3, exercise 16. He says 3N/2 - 2 is the maximum. – WaywiserTundish Nov 25 '12 at 6:51
@srbh.kmr: Indeed, I think the best is approach is to do a linear scan. For some reason it felt like I was "optimizing" on your answer but now it seems it is more of a pessimization... anyway, learned something new :) – Asiri Rathnayake Nov 25 '12 at 16:03
@AsiriRathnayake: Quoting the referenced exercise: "(I. Pohl.) Show that we can find both the maximum and minimum of a set of n elements, using at most ceiling(3n/2) - 2 comparisons; and the latter number cannot be lowered." – WaywiserTundish Nov 26 '12 at 5:04

go for divide and conquer !

1,3,2,5

for this finding min,max will take 6 comparisons

but divide them

1,3 ---> will give min 1 and max 3 in one comparison 2,5 ---> will give min 2 and max 5 in one comparison

now we can compare two mins (1,2) --> will give the final min as 1 ( one comparison) likewise two max(3,5) ---> will give the final max as 5( one comparison)

so totally four comparisons

-

A simple pseudo code for the recursive algorithm:

``````Function MAXMIN (A, low, high)
if (high − low + 1 = 2) then
if (A[low] < A[high]) then
max = A[high]; min = A[low].
return((max, min)).
else
max = A[low]; min = A[high].
return((max, min)).
end if
else
mid = low+high/2
(max_l , min_l ) = MAXMIN(A, low, mid).
(max_r , min_r ) =MAXMIN(A, mid + 1, high).
end if

Set max to the larger of max_l and max_r ;
likewise, set min to the smaller of min_l and min_r .

return((max, min)).
``````
-
``````import java.util.*;
class Maxmin
{
public static void main(String args[])
{
int[] arr = new int[10];
Scanner in = new Scanner(System.in);
int i, min=0, max=0;
for(i=0; i<=9; i++)
{
System.out.print("Enter any number: ");
arr[i] = in.nextInt();
}
min = arr[0];
for(i=0; i<=9; i++)
{
if(arr[i] > max)
{
max = arr[i];
}
if(arr[i] < min)
{
min = arr[i];
}
}
System.out.println("Maximum is: " + max);
System.out.println("Minimum is: " + min);
}
}
``````
-

A somewhat different approach, which uses integer arithmetic instead of comparisons (which wasn't explicitly prohibited)

``````for(int i=0;i<N;i++) {
xmin += x[i]-xmin & x[i]-xmin>>31;
xmax += x[i]-xmax & xmax-x[i]>>31;
}
``````
-

Brute-force is FASTER!

I would love someone to show me the error of my ways, here, but, …

I compared the actual run times of the brute-force method vs. the (more beautiful) recursive divide and conquer. Typical results (in 10,000,000 calls to each function):

``````Brute force :
0.657 seconds 10 values => 16 comparisons.  Min @ 8, Max @ 10
0.604 seconds 1000000 values => 1999985 comparisons.  Min @ 983277, Max @ 794659
Recursive :
1.879 seconds 10 values => 13 comparisons.  Min @ 8, Max @ 10
2.041 seconds 1000000 values => 1499998 comparisons.  Min @ 983277, Max @ 794659
``````

Surprisingly, the brute-force method was about 2.9 times faster for an array of 10 items, and 3.4 times faster for an array of 1,000,000 items.

Evidently, the number of comparisons is not the problem, but possibly the number of re-assignments, and the overhead of calling a recursive function (which might explain why 1,000,000 values runs slower than 10 values).

Caveats : I did this in VBA, not C, and I was comparing double-precision numbers and returning the index into the array of the Min and Max values.

Here is the code I used (class cPerformanceCounter is not included here but uses QueryPerformanceCounter for high-resolution timing) :

``````Option Explicit

'2014.07.02

Private m_l_NumberOfComparisons As Long

Sub Time_MinMax()

Const LBOUND_VALUES As Long = 1

Dim l_pcOverall As cPerformanceCounter
Dim l_d_Values() As Double
Dim i As Long, _
k As Long, _
l_l_UBoundValues As Long, _
l_l_NumberOfIterations As Long, _
l_l_IndexOfMin As Long, _
l_l_IndexOfMax As Long

Set l_pcOverall = New cPerformanceCounter

For k = 1 To 2

l_l_UBoundValues = IIf(k = 1, 10, 1000000)

ReDim l_d_Values(LBOUND_VALUES To l_l_UBoundValues)

'Assign random values
Randomize '1 '1 => the same random values to be used each time
For i = LBOUND_VALUES To l_l_UBoundValues
l_d_Values(i) = Rnd
Next i
For i = LBOUND_VALUES To l_l_UBoundValues
l_d_Values(i) = Rnd
Next i

'This keeps the total run time in the one-second neighborhood
l_l_NumberOfIterations = 10000000 / l_l_UBoundValues

'——————— Time Brute Force Method —————————————————————————————————————————
l_pcOverall.RestartTimer

For i = 1 To l_l_NumberOfIterations

m_l_NumberOfComparisons = 0

IndexOfMinAndMaxDoubleBruteForce _
l_d_Values, _
LBOUND_VALUES, _
l_l_UBoundValues, _
l_l_IndexOfMin, _
l_l_IndexOfMax

Next

l_pcOverall.ElapsedSecondsDebugPrint _
3.3, , _
" seconds Brute-Force " & l_l_UBoundValues & " values => " _
& m_l_NumberOfComparisons & " comparisons. " _
& " Min @ " & l_l_IndexOfMin _
& ", Max @ " & l_l_IndexOfMax, _
True
'——————— End Time Brute Force Method —————————————————————————————————————

'——————— Time Brute Force Using Individual Calls —————————————————————————
l_pcOverall.RestartTimer

For i = 1 To l_l_NumberOfIterations

m_l_NumberOfComparisons = 0

l_l_IndexOfMin = IndexOfMinDouble(l_d_Values)
l_l_IndexOfMax = IndexOfMaxDouble(l_d_Values)

Next

l_pcOverall.ElapsedSecondsDebugPrint _
3.3, , _
" seconds Individual  " & l_l_UBoundValues & " values => " _
& m_l_NumberOfComparisons & " comparisons. " _
& " Min @ " & l_l_IndexOfMin _
& ", Max @ " & l_l_IndexOfMax, _
True
'——————— End Time Brute Force Using Individual Calls —————————————————————

'——————— Time Recursive Divide and Conquer Method ————————————————————————
l_pcOverall.RestartTimer

For i = 1 To l_l_NumberOfIterations

m_l_NumberOfComparisons = 0

IndexOfMinAndMaxDoubleRecursiveDivideAndConquer _
l_d_Values, _
LBOUND_VALUES, _
l_l_UBoundValues, _
l_l_IndexOfMin, l_l_IndexOfMax

Next

l_pcOverall.ElapsedSecondsDebugPrint _
3.3, , _
" seconds Recursive   " & l_l_UBoundValues & " values => " _
& m_l_NumberOfComparisons & " comparisons. " _
& " Min @ " & l_l_IndexOfMin _
& ", Max @ " & l_l_IndexOfMax, _
True
'——————— End Time Recursive Divide and Conquer Method ————————————————————

Next k

End Sub

'Recursive divide and conquer
Sub IndexOfMinAndMaxDoubleRecursiveDivideAndConquer( _
i_dArray() As Double, _
i_l_LBound As Long, _
i_l_UBound As Long, _
o_l_IndexOfMin As Long, _
o_l_IndexOfMax As Long)

Dim l_l_IndexOfLeftMin As Long, _
l_l_IndexOfLeftMax As Long, _
l_l_IndexOfRightMin As Long, _
l_l_IndexOfRightMax As Long, _
l_l_IndexOfMidPoint As Long

If (i_l_LBound = i_l_UBound) Then 'Only one element

o_l_IndexOfMin = i_l_LBound
o_l_IndexOfMax = i_l_LBound

ElseIf (i_l_UBound = (i_l_LBound + 1)) Then 'Only two elements

If (i_dArray(i_l_LBound) > i_dArray(i_l_UBound)) Then
o_l_IndexOfMin = i_l_UBound
o_l_IndexOfMax = i_l_LBound
Else
o_l_IndexOfMin = i_l_LBound
o_l_IndexOfMax = i_l_UBound
End If

m_l_NumberOfComparisons = m_l_NumberOfComparisons + 1

Else 'More than two elements => recurse

l_l_IndexOfMidPoint = (i_l_LBound + i_l_UBound) / 2

'Find the min of the elements in the left half
IndexOfMinAndMaxDoubleRecursiveDivideAndConquer _
i_dArray, _
i_l_LBound, _
l_l_IndexOfMidPoint, _
l_l_IndexOfLeftMin, _
l_l_IndexOfLeftMax

'Find the min of the elements in the right half
IndexOfMinAndMaxDoubleRecursiveDivideAndConquer i_dArray, _
l_l_IndexOfMidPoint + 1, _
i_l_UBound, _
l_l_IndexOfRightMin, _
l_l_IndexOfRightMax

'Return the index of the lower of the two values returned
If (i_dArray(l_l_IndexOfLeftMin) > i_dArray(l_l_IndexOfRightMin)) Then
o_l_IndexOfMin = l_l_IndexOfRightMin
Else
o_l_IndexOfMin = l_l_IndexOfLeftMin
End If

m_l_NumberOfComparisons = m_l_NumberOfComparisons + 1

'Return the index of the lower of the two values returned
If (i_dArray(l_l_IndexOfLeftMax) > i_dArray(l_l_IndexOfRightMax)) Then
o_l_IndexOfMax = l_l_IndexOfLeftMax
Else
o_l_IndexOfMax = l_l_IndexOfRightMax
End If

m_l_NumberOfComparisons = m_l_NumberOfComparisons + 1

End If

End Sub

Sub IndexOfMinAndMaxDoubleBruteForce( _
i_dArray() As Double, _
i_l_LBound As Long, _
i_l_UBound As Long, _
o_l_IndexOfMin As Long, _
o_l_IndexOfMax As Long)

Dim i As Long

o_l_IndexOfMin = i_l_LBound
o_l_IndexOfMax = o_l_IndexOfMin

For i = i_l_LBound + 1 To i_l_UBound

'Usually we will do two comparisons
m_l_NumberOfComparisons = m_l_NumberOfComparisons + 2

If (i_dArray(i) < i_dArray(o_l_IndexOfMin)) Then

o_l_IndexOfMin = i

'We don't need to do the ElseIf comparison
m_l_NumberOfComparisons = m_l_NumberOfComparisons - 1

ElseIf (i_dArray(i) > i_dArray(o_l_IndexOfMax)) Then

o_l_IndexOfMax = i

End If
Next i

End Sub

Function IndexOfMinDouble( _
i_dArray() As Double _
) As Long

Dim i As Long

On Error GoTo EWE

IndexOfMinDouble = LBound(i_dArray)

For i = IndexOfMinDouble + 1 To UBound(i_dArray)

If (i_dArray(i) < i_dArray(IndexOfMinDouble)) Then
IndexOfMinDouble = i
End If

m_l_NumberOfComparisons = m_l_NumberOfComparisons + 1

Next i

On Error GoTo 0
Exit Function
EWE:
On Error GoTo 0
IndexOfMinDouble = MIN_LONG
End Function

Function IndexOfMaxDouble( _
i_dArray() As Double _
) As Long

Dim i As Long

On Error GoTo EWE

IndexOfMaxDouble = LBound(i_dArray)

For i = IndexOfMaxDouble + 1 To UBound(i_dArray)

If (i_dArray(i) > i_dArray(IndexOfMaxDouble)) Then
IndexOfMaxDouble = i
End If

m_l_NumberOfComparisons = m_l_NumberOfComparisons + 1

Next i

On Error GoTo 0
Exit Function
EWE:
On Error GoTo 0
IndexOfMaxDouble = MIN_LONG
End Function
``````
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Just loop over the array once, keeping track of the max and min so far.

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It is a trivial solution. I wonder how to improve it. – Michael Nov 24 '12 at 19:02
Without further specification, I have to assume this does two comparisions for each element, and thus also does 2n comparisions. – delnan Nov 24 '12 at 19:02