So I have an unsorted numeric array int[] anArray = { 1, 5, 2, 7 };
and I need to get both the value and the index of the largest value in the array which would be 7 and 3, how would I do this?

So far ive tried to use the Max() method and then use the binary search method to get the index of that max value but this doesnt work unless the array is sorted so I cant use it, when I tried that it gave me negative numbers– Edmund RojasDec 7, 2012 at 0:22

@EdmundRojas You don't need to use binary search. A plain ol' linear search works just fine for unsorted lists.– millimooseDec 7, 2012 at 0:34
21 Answers
This is not the most glamorous way but works.
(must have using System.Linq;
)
int maxValue = anArray.Max();
int maxIndex = anArray.ToList().IndexOf(maxValue);

18You save a lot of coding time, but you'll end up going through the collection twice. Dec 7, 2012 at 0:31

12You don't even need the
.ToList()
, arrays explicitly implementIList
Dec 7, 2012 at 0:36 
2@millimoose, Array has no
IndexOf
its aList<T>
method, but you could subsitute withArray.IndexOf(array,value)
Dec 7, 2012 at 0:38 
1@sa_ddam213 Arrays implement the
IList
interface, but they do so explicitly: msdn.microsoft.com/enus/library/…. (Arrays also implement the corresponding genericIList<T>
interface.) Dec 7, 2012 at 0:52 
1@sa_ddam213 No, the contract of
ToList()
is to always copy. It would be a terrible idea to have the method sometimes copy and sometimes not – this would lead to pretty crazy aliasing bugs. In fact the implementation ofToList()
is more or lessreturn new List(source)
Dec 7, 2012 at 1:13
int[] anArray = { 1, 5, 2, 7 };
// Finding max
int m = anArray.Max();
// Positioning max
int p = Array.IndexOf(anArray, m);
If the index is not sorted, you have to iterate through the array at least once to find the highest value. I'd use a simple for
loop:
int? maxVal = null; //nullable so this works even if you have all superlow negatives
int index = 1;
for (int i = 0; i < anArray.Length; i++)
{
int thisNum = anArray[i];
if (!maxVal.HasValue  thisNum > maxVal.Value)
{
maxVal = thisNum;
index = i;
}
}
This is more verbose than something using LINQ or other oneline solutions, but it's probably a little faster. There's really no way to make this faster than O(N).

5You could save one iteration by initializing
maxVal
to the array value at index 0 (assuming the array is at least length 1),index
to 0, and starting the for loop ati = 1
. Dec 6, 2017 at 14:57
A succinct oneliner:
var (number, index) = anArray.Select((n, i) => (n, i)).Max();
Test case:
var anArray = new int[] { 1, 5, 7, 4, 2 };
var (number, index) = anArray.Select((n, i) => (n, i)).Max();
Console.WriteLine($"Maximum number = {number}, on index {index}.");
// Maximum number = 7, on index 2.
Features:
 Uses Linq (not as optimized as vanilla, but the tradeoff is less code).
 Does not need to sort.
 Computational complexity: O(n).
 Space complexity: O(n).
Remarks:
 Make sure the number (and not the index) is the first element in the tuple because tuple sorting is done by comparing tuple items from left to right.

1

2It should be pointed out that for this to work, the item being maxedby must be first Aug 26, 2020 at 20:31

What do you mean @CaiusJard? As shown in the test case, the maximum item was correctly found and it was last. Aug 27, 2020 at 22:56

1First in the Tuple, for example
anArray.Select((n, i) => ( Index: i, Number: n)).Max()
finds the max index rather than the max number because of the way tuples are compared (item1 is most significant etc) Aug 27, 2020 at 23:02 
Fair enough @CaiusJard, I added a remark to point that out. Thanks. Aug 29, 2020 at 19:15
The obligatory LINQ one^{[1]}liner:
var max = anArray.Select((value, index) => new {value, index})
.OrderByDescending(vi => vi.value)
.First();
(The sorting is probably a performance hit over the other solutions.)
[1]: For given values of "one".

14Just to add this solution is O(nlogn) complexity at best. Finding max can be obtained in O(n) time for an unsorted array. Jun 18, 2014 at 13:52
Here are two approaches. You may want to add handling for when the array is empty.
public static void FindMax()
{
// Advantages:
// * Functional approach
// * Compact code
// Cons:
// * We are indexing into the array twice at each step
// * The Range and IEnumerable add a bit of overhead
// * Many people will find this code harder to understand
int[] array = { 1, 5, 2, 7 };
int maxIndex = Enumerable.Range(0, array.Length).Aggregate((max, i) => array[max] > array[i] ? max : i);
int maxInt = array[maxIndex];
Console.WriteLine($"Maximum int {maxInt} is found at index {maxIndex}");
}
public static void FindMax2()
{
// Advantages:
// * Nearoptimal performance
int[] array = { 1, 5, 2, 7 };
int maxIndex = 1;
int maxInt = Int32.MinValue;
// Modern C# compilers optimize the case where we put array.Length in the condition
for (int i = 0; i < array.Length; i++)
{
int value = array[i];
if (value > maxInt)
{
maxInt = value;
maxIndex = i;
}
}
Console.WriteLine($"Maximum int {maxInt} is found at index {maxIndex}");
}
int[] numbers = new int[7]{45,67,23,45,19,85,64};
int smallest = numbers[0];
for (int index = 0; index < numbers.Length; index++)
{
if (numbers[index] < smallest) smallest = numbers[index];
}
Console.WriteLine(smallest);
public static class ArrayExtensions
{
public static int MaxIndexOf<T>(this T[] input)
{
var max = input.Max();
int index = Array.IndexOf(input, max);
return index;
}
}
This works for all variable types...
var array = new int[]{1, 2, 4, 10, 0, 2};
var index = array.MaxIndexOf();
var array = new double[]{1.0, 2.0, 4.0, 10.0, 0.0, 2.0};
var index = array.MaxIndexOf();
anArray.Select((n, i) => new { Value = n, Index = i })
.Where(s => s.Value == anArray.Max());

This is an O(n^2) solution, because you are computing anArray.Max() on every iteration. That will get very slow for large arrays.– NeilApr 2, 2016 at 13:55
Output for bellow code:
00:00:00.3279270  max1 00:00:00.2615935  max2 00:00:00.6010360  max3 (arr.Max())
With 100000000 ints in array not very big difference but still...
class Program
{
static void Main(string[] args)
{
int[] arr = new int[100000000];
Random randNum = new Random();
for (int i = 0; i < arr.Length; i++)
{
arr[i] = randNum.Next(100000000, 100000000);
}
Stopwatch stopwatch1 = new Stopwatch();
Stopwatch stopwatch2 = new Stopwatch();
Stopwatch stopwatch3 = new Stopwatch();
stopwatch1.Start();
var max = GetMaxFullIterate(arr);
Debug.WriteLine( stopwatch1.Elapsed.ToString());
stopwatch2.Start();
var max2 = GetMaxPartialIterate(arr);
Debug.WriteLine( stopwatch2.Elapsed.ToString());
stopwatch3.Start();
var max3 = arr.Max();
Debug.WriteLine(stopwatch3.Elapsed.ToString());
}
private static int GetMaxPartialIterate(int[] arr)
{
var max = arr[0];
var idx = 0;
for (int i = arr.Length / 2; i < arr.Length; i++)
{
if (arr[i] > max)
{
max = arr[i];
}
if (arr[idx] > max)
{
max = arr[idx];
}
idx++;
}
return max;
}
private static int GetMaxFullIterate(int[] arr)
{
var max = arr[0];
for (int i = 0; i < arr.Length; i++)
{
if (arr[i] > max)
{
max = arr[i];
}
}
return max;
}
public static void Main()
{
int a,b=0;
int []arr={1, 2, 2, 3, 3, 4, 5, 6, 5, 7, 7, 7, 100, 8, 1};
for(int i=arr.Length1 ; i>1 ; i)
{
a = arr[i];
if(a > b)
{
b=a;
}
}
Console.WriteLine(b);
}
Old post, but this is super easy with Lists:
For Maximum:
List<int> lst = new List<int>(YourArray);
int Max = lst.OrderByDescending(x => x).First();
For Minimum:
List<int> lst = new List<int>(YourArray);
int Max = lst.OrderBy(x => x).First();
Of course you can substitute "int" data type with any numeric variable type (float, decimal, etc).
This is very high performance BTW and beats any other method (IMHO)
int[] Data= { 1, 212, 333,2,12,3311,122,23 };
int large = Data.Max();
Console.WriteLine(large);

1Your answer only gives the highest value, but the asker requested for both highest value and index of the highest value.– CardinApr 5, 2016 at 7:19

can't find max function from the array, unless you used "System.Linq" Dec 10, 2020 at 9:53
Here is a LINQ solution which is O(n) with decent constant factors:
int[] anArray = { 1, 5, 2, 7, 1 };
int index = 0;
int maxIndex = 0;
var max = anArray.Aggregate(
(oldMax, element) => {
++index;
if (element <= oldMax)
return oldMax;
maxIndex = index;
return element;
}
);
Console.WriteLine("max = {0}, maxIndex = {1}", max, maxIndex);
But you should really write an explicit for
lop if you care about performance.
Just another perspective using DataTable
. Declare a DataTable
with 2 columns called index
and val
. Add an AutoIncrement
option and both AutoIncrementSeed
and AutoIncrementStep
values 1
to the index
column. Then use a foreach
loop and insert each array item into the datatable
as a row. Then by using Select
method, select the row having the maximum value.
Code
int[] anArray = { 1, 5, 2, 7 };
DataTable dt = new DataTable();
dt.Columns.AddRange(new DataColumn[2] { new DataColumn("index"), new DataColumn("val")});
dt.Columns["index"].AutoIncrement = true;
dt.Columns["index"].AutoIncrementSeed = 1;
dt.Columns["index"].AutoIncrementStep = 1;
foreach(int i in anArray)
dt.Rows.Add(null, i);
DataRow[] dr = dt.Select("[val] = MAX([val])");
Console.WriteLine("Max Value = {0}, Index = {1}", dr[0][1], dr[0][0]);
Output
Max Value = 7, Index = 4
If you know max index accessing the max value is immediate. So all you need is max index.
int max=0;
for(int i = 1; i < arr.Length; i++)
if (arr[i] > arr[max]) max = i;
This is a C# Version. It's based on the idea of sort the array.
public int solution(int[] A)
{
// write your code in C# 6.0 with .NET 4.5 (Mono)
Array.Sort(A);
var max = A.Max();
if(max < 0)
return 1;
else
for (int i = 1; i < max; i++)
{
if(!A.Contains(i)) {
return i;
}
}
return max + 1;
}
Consider following:
/// <summary>
/// Returns max value
/// </summary>
/// <param name="arr">array to search in</param>
/// <param name="index">index of the max value</param>
/// <returns>max value</returns>
public static int MaxAt(int[] arr, out int index)
{
index = 1;
int max = Int32.MinValue;
for (int i = 0; i < arr.Length; i++)
{
if (arr[i] > max)
{
max = arr[i];
index = i;
}
}
return max;
}
Usage:
int m, at;
m = MaxAt(new int[]{1,2,7,3,4,5,6}, out at);
Console.WriteLine("Max: {0}, found at: {1}", m, at);
This can be done with a bodiless for
loop, if we're heading towards golf ;)
//a is the array
int mi = a.Length  1;
for (int i=1; ++i<a.Length1; mi=a[mi]<a[i]?i:mi) ;
The check of ++i<a.Length1
omits checking the last index. We don't mind this if we set it up as if the max index is the last index to start with.. When the loop runs for the other elements it will finish and one or the other thing is true:
 we found a new max value and hence a new max index
mi
 the last index was the max value all along, so we didn't find a new
mi
, and we stuck with the initialmi
The real work is done by the postloop modifiers:
 is the max value (
a[mi]
i.e. array indexed bymi
) we found so far, less than the current item? yes, then store a new
mi
by rememberingi
,  no then store the existing
mi
(noop)
 yes, then store a new
At the end of the operation you have the index at which the max is to be found. Logically then the max value is a[mi]
I couldn't quite see how the "find max and index of max" really needed to track the max value too, given that if you have an array, and you know the index of the max value, the actual value of the max value is a trivial case of using the index to index the array..
Another answer in this long list, but I think it's worth it, because it provides some benefits that most (or all?) other answers don't:
 The method below loops only once through the collection, therefore the order is O(N).
 The method finds ALL indices of the maximum values.
 The method can be used to find the indices of any comparison:
min
,max
,equals
,not equals
, etc.  The method can look into objects via a LINQ selector.
Method:
///
/// <summary>
/// Get the indices of all values that meet the condition that is defined by the comparer.
/// </summary>
/// <typeparam name="TSource">The type of the values in the source collection.</typeparam>
/// <typeparam name="TCompare">The type of the values that are compared.</typeparam>
/// <param name="i_collection">The collection of values that is analysed.</param>
/// <param name="i_selector">The selector to retrieve the comparevalues from the sourcevalues.</param>
/// <param name="i_comparer">The comparer that is used to compare the values of the collection.</param>
/// <returns>The indices of all values that meet the condition that is defined by the comparer.</returns>
/// Create <see cref="IComparer{T}"/> from comparison function:
/// Comparer{T}.Create ( comparison )
/// Comparison examples:
///  max: (a, b) => a.CompareTo (b)
///  min: (a, b) => (a.CompareTo (b))
///  == x: (a, b) => a == 4 ? 0 : 1
///  != x: (a, b) => a != 4 ? 0 : 1
///
public static IEnumerable<int> GetIndices<TSource, TCompare> (this IEnumerable<TSource> i_collection,
Func<TSource, TCompare> i_selector,
IComparer<TCompare> i_comparer)
{
if (i_collection == null)
throw new ArgumentNullException (nameof (i_collection));
if (!i_collection.Any ())
return new int[0];
int index = 0;
var indices = new List<int> ();
TCompare reference = i_selector (i_collection.First ());
foreach (var value in i_collection)
{
var compare = i_selector (value);
int result = i_comparer.Compare (compare, reference);
if (result > 0)
{
reference = compare;
indices.Clear ();
indices.Add (index);
}
else if (result == 0)
indices.Add (index);
index++;
}
return indices;
}
If you don't need the selector, then change the method to
public static IEnumerable<int> GetIndices<TCompare> (this IEnumerable<TCompare> i_collection,
IComparer<TCompare> i_comparer)
and remove all occurences of i_selector
.
Proof of concept:
//########## test #1: int array ##########
int[] test = { 1, 5, 4, 9, 2, 7, 4, 6, 5, 9, 4 };
// get indices of maximum:
var indices = test.GetIndices (t => t, Comparer<int>.Create ((a, b) => a.CompareTo (b)));
// indices: { 3, 9 }
// get indices of all '4':
indices = test.GetIndices (t => t, Comparer<int>.Create ((a, b) => a == 4 ? 0 : 1));
// indices: { 2, 6, 10 }
// get indices of all except '4':
indices = test.GetIndices (t => t, Comparer<int>.Create ((a, b) => a != 4 ? 0 : 1));
// indices: { 0, 1, 3, 4, 5, 7, 8, 9 }
// get indices of all '15':
indices = test.GetIndices (t => t, Comparer<int>.Create ((a, b) => a == 15 ? 0 : 1));
// indices: { }
//########## test #2: named tuple array ##########
var datas = new (object anything, double score)[]
{
(999, 0.1),
(new object (), 0.42),
("hello", 0.3),
(new Exception (), 0.16),
("abcde", 0.42)
};
// get indices of highest score:
indices = datas.GetIndices (data => data.score, Comparer<double>.Create ((a, b) => a.CompareTo (b)));
// indices: { 1, 4 }
Enjoy! :)
Finds the biggest and the smallest number in the array:
int[] arr = new int[] {35,28,20,89,63,45,12};
int big = 0;
int little = 0;
for (int i = 0; i < arr.Length; i++)
{
Console.WriteLine(arr[i]);
if (arr[i] > arr[0])
{
big = arr[i];
}
else
{
little = arr[i];
}
}
Console.WriteLine("most big number inside of array is " + big);
Console.WriteLine("most little number inside of array is " + little);

1it's going to return the last value that is bigger/smaller than the first value in the array, not the min/max. Feb 16, 2020 at 17:56