LINQ Aggregate algorithm explained

This might sound lame, but I have not been able to find a really good explanation of `Aggregate`.

Good means short, descriptive, comprehensive with a small and clear example.

The easiest-to-understand definition of `Aggregate` is that it performs an operation on each element of the list taking into account the operations that have gone before. That is to say it performs the action on the first and second element and carries the result forward. Then it operates on the previous result and the third element and carries forward. etc.

Example 1. Summing numbers

``````var nums = new[]{1,2,3,4};
var sum = nums.Aggregate( (a,b) => a + b);
Console.WriteLine(sum); // output: 10 (1+2+3+4)
``````

This adds `1` and `2` to make `3`. Then adds `3` (result of previous) and `3` (next element in sequence) to make `6`. Then adds `6` and `4` to make `10`.

Example 2. create a csv from an array of strings

``````var chars = new []{"a","b","c", "d"};
var csv = chars.Aggregate( (a,b) => a + ',' + b);
Console.WriteLine(csv); // Output a,b,c,d
``````

This works in much the same way. Concatenate `a` a comma and `b` to make `a,b`. Then concatenates `a,b` with a comma and `c` to make `a,b,c`. and so on.

Example 3. Multiplying numbers using a seed

For completeness, there is an overload of `Aggregate` which takes a seed value.

``````var multipliers = new []{10,20,30,40};
var multiplied = multipliers.Aggregate(5, (a,b) => a * b);
Console.WriteLine(multiplied); //Output 1200000 ((((5*10)*20)*30)*40)
``````

Much like the above examples, this starts with a value of `5` and multiplies it by the first element of the sequence `10` giving a result of `50`. This result is carried forward and multiplied by the next number in the sequence `20` to give a result of `1000`. This continues through the remaining 2 element of the sequence.

Example 2, above, uses string concatenation to create a list of values separated by a comma. This is a simplistic way to explain the use of `Aggregate` which was the intention of this answer. However, if using this technique to actually create a large amount of comma separated data, it would be more appropriate to use a `StringBuilder`, and this is entirely compatible with `Aggregate` using the seeded overload to initiate the `StringBuilder`.

``````var chars = new []{"a","b","c", "d"};
var csv = chars.Aggregate(new StringBuilder(), (a,b) => {
if(a.Length>0)
a.Append(",");
a.Append(b);
return a;
});
Console.WriteLine(csv);
``````

Updated example: http://rextester.com/YZCVXV6464

• Another explanation for the first description is that the function you provide always combines the first two members until the array is shrinked to one element. So `[1,2,3,4]` will be `[3,3,4]` then `[6,4]` and at last ``. But instead of returning an array of a single value you just get the value itself. – David Raab Jul 22 '14 at 22:04
• Can I early break/exit from an Aggregate function? For example, chars.Aggregate((a, b) => {if(a == 'a') break the whole aggregate else return a + ', ' + b}) – Jeff Tian Sep 22 '14 at 9:30
• @JeffTian - I would suggest chaining a `TakeWhile` then an `Aggregate` - thats the beatuty of Enumerable extensions - they are easily chainable. So you end up with `TakeWhile(a => a == 'a').Aggregate(....)`. See this example: rextester.com/WPRA60543 – Jamiec Sep 22 '14 at 12:34
• Two suggestions: show how seed could be use to do concatenation without the quadratic behaviour of your example, and explain the asymmetric roles of the two arguments (the first is the accumulator, the second is the value). – Clément Jul 1 '15 at 18:53
• another common usage (so far the only i have even seen in production code) is to get min or max items like `var biggestAccount = Accounts.Aggregate((a1, a2) => a1.Amount >= a2.Amount ? a1 : a2);` – Franck Mar 24 '17 at 18:02

It partly depends on which overload you're talking about, but the basic idea is:

• Iterate over the sequence. For each value in the sequence:
• Apply a user-specified function to transform `(currentValue, sequenceValue)` into `(nextValue)`
• Set `currentValue = nextValue`
• Return the final `currentValue`

You may find the `Aggregate` post in my Edulinq series useful - it includes a more detailed description (including the various overloads) and implementations.

One simple example is using `Aggregate` as an alternative to `Count`:

``````// 0 is the seed, and for each item, we effectively increment the current value.
// In this case we can ignore "item" itself.
int count = sequence.Aggregate(0, (current, item) => current + 1);
``````

Or perhaps summing all the lengths of strings in a sequence of strings:

``````int total = sequence.Aggregate(0, (current, item) => current + item.Length);
``````

Personally I rarely find `Aggregate` useful - the "tailored" aggregation methods are usually good enough for me.

• @Jon Are there asynchronous variations of Aggregate that split the items into a tree so that work can be split between cores? It seems the design of the method is consistent with the concepts of "reduce" or "fold", but I don't know if it really is doing that under the hood, or simply iterating through the list of items. – AaronLS Nov 1 '12 at 22:18
• @Jon : the edulink mentioned above is not working can you redirect me to the right link. And can you please be more specific about the term "tailored" aggregation functions that you used in your answer. – Koushik Oct 16 '14 at 13:55
• @Koushik: I've fixed the link in the post. By "tailored" aggregation functions I mean things like Max/Min/Count/Sum. – Jon Skeet Oct 16 '14 at 15:08

Super short Aggregate works like fold in Haskell/ML/F#.

Slightly longer .Max(), .Min(), .Sum(), .Average() all iterates over the elements in a sequence and aggregates them using the respective aggregate function. .Aggregate () is generalized aggregator in that it allows the developer to specify the start state (aka seed) and the aggregate function.

I know you asked for a short explaination but I figured as others gave a couple of short answers I figured you would perhaps be interested in a slightly longer one

Long version with code One way to illustrate what does it could be show how you implement Sample Standard Deviation once using foreach and once using .Aggregate. Note: I haven't prioritized performance here so I iterate several times over the colleciton unnecessarily

First a helper function used to create a sum of quadratic distances:

``````static double SumOfQuadraticDistance (double average, int value, double state)
{
var diff = (value - average);
return state + diff * diff;
}
``````

Then Sample Standard Deviation using ForEach:

``````static double SampleStandardDeviation_ForEach (
this IEnumerable<int> ints)
{
var length = ints.Count ();
if (length < 2)
{
return 0.0;
}

const double seed = 0.0;
var average = ints.Average ();

var state = seed;
foreach (var value in ints)
{
state = SumOfQuadraticDistance (average, value, state);
}

return Math.Sqrt (sumOfQuadraticDistance / (length - 1));
}
``````

Then once using .Aggregate:

``````static double SampleStandardDeviation_Aggregate (
this IEnumerable<int> ints)
{
var length = ints.Count ();
if (length < 2)
{
return 0.0;
}

const double seed = 0.0;
var average = ints.Average ();

.Aggregate (
seed,
(state, value) => SumOfQuadraticDistance (average, value, state)
);

return Math.Sqrt (sumOfQuadraticDistance / (length - 1));
}
``````

Note that these functions are identical except for how sumOfQuadraticDistance is calculated:

``````var state = seed;
foreach (var value in ints)
{
state = SumOfQuadraticDistance (average, value, state);
}
``````

Versus:

``````var sumOfQuadraticDistance = ints
.Aggregate (
seed,
(state, value) => SumOfQuadraticDistance (average, value, state)
);
``````

So what .Aggregate does is that it encapsulates this aggregator pattern and I expect that the implementation of .Aggregate would look something like this:

``````public static TAggregate Aggregate<TAggregate, TValue> (
this IEnumerable<TValue> values,
TAggregate seed,
Func<TAggregate, TValue, TAggregate> aggregator
)
{
var state = seed;

foreach (var value in values)
{
state = aggregator (state, value);
}

return state;
}
``````

Using the Standard deviation functions would look something like this:

``````var ints = new[] {3, 1, 4, 1, 5, 9, 2, 6, 5, 4};
var average = ints.Average ();
var sampleStandardDeviation = ints.SampleStandardDeviation_Aggregate ();
var sampleStandardDeviation2 = ints.SampleStandardDeviation_ForEach ();

Console.WriteLine (average);
Console.WriteLine (sampleStandardDeviation);
Console.WriteLine (sampleStandardDeviation2);
``````

IMHO

So does .Aggregate help readability? In general I love LINQ because I think .Where, .Select, .OrderBy and so on greatly helps readability (if you avoid inlined hierarhical .Selects). Aggregate has to be in Linq for completeness reasons but personally I am not so convinced that .Aggregate adds readability compared to a well written foreach.

• +1 Excellent! But extension methods `SampleStandardDeviation_Aggregate()` and `SampleStandardDeviation_ForEach()` cannot be `private` (by default in absence of an access qualifier), so should have been accrued by either `public` or `internal`, it seems to me – Fulproof Apr 10 '13 at 13:25
• FYI: If I remember correctly the extension methods in my sample was part of the same class that used them ==> private works in this case. – Just another metaprogrammer Jul 31 '13 at 14:38

A picture is worth a thousand words

Reminder: `Func<A, B, C>` is a function with two inputs of type `A` and `B`, that returns a `C`.

``````A Aggregate<A>(IEnumerable<A> a, Func<A, A, A> f)
`````` Example:

``````new[]{1,2,3,4}.Aggregate((x, y) => x + y);  // 10
``````

This overload is simple, but it has the following limitations:

• the sequence must contain at least one element,
otherwise the function will throw an `InvalidOperationException`.
• elements and result must be of the same type.

``````B Aggregate<A, B>(IEnumerable<A> a, B bIn, Func<B, A, B> f)
`````` Example:

``````var hayStack = new[] {"straw", "needle", "straw", "straw", "needle"};
var nNeedles = hayStack.Aggregate(0, (n, e) => e == "needle" ? n+1 : n);  // 2
``````

• a seed value must be provided (`bIn`).
• the collection can be empty,
in this case, the function will yield the seed value as result.
• elements and result can have different types.

``````C Aggregate<A,B,C>(IEnumerable<A> a, B bIn, Func<B,A,B> f, Func<B,C> f2)
``````

The third overload is not very useful IMO.
The same can be written more succinctly by using overload 2 followed by a function that transforms its result.

The illustrations are adapted from this excellent blogpost.

• This would be a great answer.... on a question about Haskel. But there is no overload of `Aggegate` in .net which takes a `Func<T, T, T>`. – Jamiec Apr 17 '17 at 17:17
• Yes there is. You use it in your own answer! – 3dGrabber Apr 18 '17 at 8:07
• Upvoting because you carefully describe what happens when the sequence is empty. Let N be the number of elements in the source. We observe that the overload that does not take a `seed`, applies the accumulator function N-1 times; while the other overloads (that do take a `seed`) apply the accumulator function N times. – Jeppe Stig Nielsen May 7 '18 at 14:18

Aggregate is basically used to Group or Sum up data.

According to MSDN "Aggregate Function Applies an accumulator function over a sequence."

Example 1: Add all the numbers in a array.

``````int[] numbers = new int[] { 1,2,3,4,5 };
int aggregatedValue = numbers.Aggregate((total, nextValue) => total + nextValue);
``````

*important: The initial aggregate value by default is the 1 element in the sequence of collection. i.e: the total variable initial value will be 1 by default.

variable explanation

total: it will hold the sum up value(aggregated value) returned by the func.

nextValue: it is the next value in the array sequence. This value is than added to the aggregated value i.e total.

Example 2: Add all items in an array. Also set the initial accumulator value to start adding with from 10.

``````int[] numbers = new int[] { 1,2,3,4,5 };
int aggregatedValue = numbers.Aggregate(10, (total, nextValue) => total + nextValue);
``````

arguments explanation:

the first argument is the initial(starting value i.e seed value) which will be used to start addition with the next value in the array.

the second argument is a func which is a func that takes 2 int.

1.total: this will hold same as before the sum up value(aggregated value) returned by the func after the calculation.

2.nextValue: : it is the next value in the array sequence. This value is than added to the aggregated value i.e total.

Also debugging this code will give you a better understanding of how aggregate work.

Learned a lot from Jamiec's answer.

If the only need is to generate CSV string, you may try this.

``````var csv3 = string.Join(",",chars);
``````

Here is a test with 1 million strings

``````0.28 seconds = Aggregate w/ String Builder
0.30 seconds = String.Join
``````

Source code is here

In addition to all the great answers here already, I've also used it to walk an item through a series of transformation steps.

If a transformation is implemented as a `Func<T,T>`, you can add several transformations to a `List<Func<T,T>>` and use `Aggregate` to walk an instance of `T` through each step.

A more concrete example

You want to take a `string` value, and walk it through a series of text transformations that could be built programatically.

``````var transformationPipeLine = new List<Func<string, string>>();
transformationPipeLine.Add((input) => input.Substring(0, input.Length - 1));

var text = "    cat   ";
var output = transformationPipeLine.Aggregate(text, (input, transform)=> transform(input));
Console.WriteLine(output);
``````

This will create a chain of transformations: Remove leading and trailing spaces -> remove first character -> remove last character -> convert to upper-case. Steps in this chain can be added, removed, or reordered as needed, to create whatever kind of transformation pipeline is required.

The end result of this specific pipeline, is that `" cat "` becomes `"A"`.

This can become very powerful once you realize that `T` can be anything. This could be used for image transformations, like filters, using `BitMap` as an example;

A short and essential definition might be this: Linq Aggregate extension method allows to declare a sort of recursive function applied on the elements of a list, the operands of whom are two: the elements in the order in which they are present into the list, one element at a time, and the result of the previous recursive iteration or nothing if not yet recursion.

In this way you can compute the factorial of numbers, or concatenate strings.

This is an explanation about using `Aggregate` on a Fluent API such as Linq Sorting.

``````var list = new List<Student>();
var sorted = list
.OrderBy(s => s.LastName)
.ThenBy(s => s.FirstName)
.ThenBy(s => s.Age)
.ThenBy(s => s.TotalCourses);
``````

and lets see we want to implement a sort function that take a set of fields, this is very easy using `Aggregate` instead of a for-loop, like this:

``````public static IOrderedEnumerable<Student> MySort(
this List<Student> list,
params Func<Student, object>[] fields)
{
var firstField = fields.First();
var otherFields = fields.Skip(1);

var init = list.OrderBy(firstField);
return otherFields.Skip(1).Aggregate(init, (resultList, current) => resultList.ThenBy(current));
}
``````

And we can use it like this:

``````var sorted = list.MySort(
s => s.LastName,
s => s.FirstName,
s => s.Age,
s => s.TotalCourses);
``````

Aggregate used to sum columns in a multi dimensional integer array

``````        int[][] nonMagicSquare =
{
new int[] {  3,  1,  7,  8 },
new int[] {  2,  4, 16,  5 },
new int[] { 11,  6, 12, 15 },
new int[] {  9, 13, 10, 14 }
};

IEnumerable<int> rowSums = nonMagicSquare
.Select(row => row.Sum());
IEnumerable<int> colSums = nonMagicSquare
.Aggregate(
(priorSums, currentRow) =>
priorSums.Select((priorSum, index) => priorSum + currentRow[index]).ToArray()
);
``````

Select with index is used within the Aggregate func to sum the matching columns and return a new Array; { 3 + 2 = 5, 1 + 4 = 5, 7 + 16 = 23, 8 + 5 = 13 }.

``````        Console.WriteLine("rowSums: " + string.Join(", ", rowSums)); // rowSums: 19, 27, 44, 46
Console.WriteLine("colSums: " + string.Join(", ", colSums)); // colSums: 25, 24, 45, 42
``````

But counting the number of trues in a Boolean array is more difficult since the accumulated type (int) differs from the source type (bool); here a seed is necessary in order to use the second overload.

``````        bool[][] booleanTable =
{
new bool[] { true, true, true, false },
new bool[] { false, false, false, true },
new bool[] { true, false, false, true },
new bool[] { true, true, false, false }
};

IEnumerable<int> rowCounts = booleanTable
.Select(row => row.Select(value => value ? 1 : 0).Sum());
IEnumerable<int> seed = new int[booleanTable.First().Length];
IEnumerable<int> colCounts = booleanTable
.Aggregate(seed,
(priorSums, currentRow) =>
priorSums.Select((priorSum, index) => priorSum + (currentRow[index] ? 1 : 0)).ToArray()
);

Console.WriteLine("rowCounts: " + string.Join(", ", rowCounts)); // rowCounts: 3, 1, 2, 2
Console.WriteLine("colCounts: " + string.Join(", ", colCounts)); // colCounts: 3, 2, 1, 2
``````

Everyone has given his explanation. My explanation is like that.

Aggregate method applies a function to each item of a collection. For example, let's have collection { 6, 2, 8, 3 } and the function Add (operator +) it does (((6+2)+8)+3) and returns 19

``````var numbers = new List<int> { 6, 2, 8, 3 };
int sum = numbers.Aggregate(func: (result, item) => result + item);
// sum: (((6+2)+8)+3) = 19
``````

In this example there is passed named method Add instead of lambda expression.

``````var numbers = new List<int> { 6, 2, 8, 3 };