# Why are Where and Select outperforming just Select?

I have a class, like this:

``````public class MyClass
{
public int Value { get; set; }
public bool IsValid { get; set; }
}
``````

In actual fact it's much larger, but this recreates the problem (weirdness).

I want to get the sum of the `Value`, where the instance is valid. So far, I've found two solutions to this.

## The first one is this:

``````int result = myCollection.Where(mc => mc.IsValid).Select(mc => mc.Value).Sum();
``````

## The second one, however, is this:

``````int result = myCollection.Select(mc => mc.IsValid ? mc.Value : 0).Sum();
``````

I want to get the most efficient method. I, at first, thought that the second one would be more efficient. Then the theoretical part of me started going "Well, one is O(n + m + m), the other one is O(n + n). The first one should perform better with more invalids, while the second one should perform better with less". I thought that they would perform equally. EDIT: And then @Martin pointed out that the Where and the Select were combined, so it should actually be O(m + n). However, if you look below, it seems like this is not related.

# So I put it to the test.

(It's 100+ lines, so I thought it was better to post it as a Gist.)
The results were... interesting.

## With 0% tie tolerance:

The scales are in the favour of `Select` and `Where`, by about ~30 points.

``` How much do you want to be the disambiguation percentage? 0 Starting benchmarking. Ties: 0 Where + Select: 65 Select: 36 ```

## With 2% tie tolerance:

It's the same, except that for some they were within 2%. I'd say that's a minimum margin of error. `Select` and `Where` now have just a ~20 point lead.

``` How much do you want to be the disambiguation percentage? 2 Starting benchmarking. Ties: 6 Where + Select: 58 Select: 37 ```

## With 5% tie tolerance:

This is what I'd say to be my maximum margin of error. It makes it a bit better for the `Select`, but not much.

``` How much do you want to be the disambiguation percentage? 5 Starting benchmarking. Ties: 17 Where + Select: 53 Select: 31 ```

## With 10% tie tolerance:

This is way out of my margin of error, but I'm still interested in the result. Because it gives the `Select` and `Where` the twenty point lead it's had for a while now.

``` How much do you want to be the disambiguation percentage? 10 Starting benchmarking. Ties: 36 Where + Select: 44 Select: 21 ```

## With 25% tie tolerance:

This is way, way out of my margin of error, but I'm still interested in the result, because the `Select` and `Where` still (nearly) keep their 20 point lead. It seems like it's outclassing it in a distinct few, and that's what giving it the lead.

``` How much do you want to be the disambiguation percentage? 25 Starting benchmarking. Ties: 85 Where + Select: 16 Select: 0 ```

Now, I'm guessing that the 20 point lead came from the middle, where they're both bound to get around the same performance. I could try and log it, but it would be a whole load of information to take in. A graph would be better, I guess.

So that's what I did.

It shows that the `Select` line keeps steady (expected) and that the `Select + Where` line climbs up (expected). However, what puzzles me is why it doesn't meet with the `Select` at 50 or earlier: in fact I was expecting earlier than 50, as an extra enumerator had to be created for the `Select` and `Where`. I mean, this shows the 20-point lead, but it doesn't explain why. This, I guess, is the main point of my question.

# Why does it behave like this? Should I trust it? If not, should I use the other one or this one?

As @KingKong mentioned in the comments, you can also use `Sum`'s overload that takes a lambda. So my two options are now changed to this:

## First:

``````int result = myCollection.Where(mc => mc.IsValid).Sum(mc => mc.Value);
``````

## Second:

``````int result = myCollection.Sum(mc => mc.IsValid ? mc.Value : 0);
``````

I'm going to make it a bit shorter, but:

``` How much do you want to be the disambiguation percentage? 0 Starting benchmarking. Ties: 0 Where: 60 Sum: 41 How much do you want to be the disambiguation percentage? 2 Starting benchmarking. Ties: 8 Where: 55 Sum: 38 How much do you want to be the disambiguation percentage? 5 Starting benchmarking. Ties: 21 Where: 49 Sum: 31 How much do you want to be the disambiguation percentage? 10 Starting benchmarking. Ties: 39 Where: 41 Sum: 21 How much do you want to be the disambiguation percentage? 25 Starting benchmarking. Ties: 85 Where: 16 Sum: 0 ```

The twenty-point lead is still there, meaning it doesn't have to do with the `Where` and `Select` combination pointed out by @Marcin in the comments.

Thanks for reading through my wall of text! Also, if you're interested, here's the modified version that logs the CSV that Excel takes in.

• I'd say it depends on how expensive the sum and access to `mc.Value` are. Commented Aug 20, 2013 at 9:48
• @It'sNotALie. `Where`+`Select` does not cause two separated iterations over input collection. LINQ to Objects optimize it into one iteration. Read More on my blog post Commented Aug 20, 2013 at 9:48
• Interesting. Let me just point out that a for loop over an array would be 10x faster than the best LINQ solution. So if you go hunting for perf, don't use LINQ in the first place.
– usr
Commented Aug 20, 2013 at 11:00
• Sometimes people ask after real research, this is one example question: I am not C# user came from Hot-question-list. Commented Aug 20, 2013 at 11:35
• @WiSaGaN That's a good point. However, if this is due to branch vs conditional move, we would expect to see the most dramatic difference at 50%/50%. Here, we see the most dramatic differences at the ends, where branching is most predictable. If the Where is a branch, and the ternary is a conditional move, then we would expect the Where times to come back down when all the elements are valid, but it never comes back down. Commented Aug 21, 2013 at 4:53

`Select` iterates once over the entire set and, for each item, performs a conditional branch (checking for validity) and a `+` operation.

`Where+Select` creates an iterator that skips invalid elements (doesn't `yield` them), performing a `+` only on the valid items.

So, the cost for a `Select` is:

`t(s) = n * ( cost(check valid) + cost(+) )`

And for `Where+Select`:

`t(ws) = n * ( cost(check valid) + p(valid) * (cost(yield) + cost(+)) )`

Where:

• `p(valid)` is the probability that an item in the list is valid.
• `cost(check valid)` is the cost of the branch that checks for validity
• `cost(yield)` is the cost of constructing the new state of the `where` iterator, which is more complex than the simple iterator that the `Select` version uses.

As you can see, for a given `n`, the `Select` version is a constant, whereas the `Where+Select` version is a linear equation with `p(valid)` as a variable. The actual values of the costs determine the intersection point of the two lines, and since `cost(yield)` can be different from `cost(+)`, they don't necessarily intersect at `p(valid)`=0.5.

• +1 for being the only answer (so far) that actually addresses the question, doesn't guess the answer and doesn't just generate "me too!" statistics. Commented Aug 20, 2013 at 13:21
• Technically LINQ methods creates expressions trees that are run over the whole collection once instead of "sets". Commented Aug 20, 2013 at 13:36
• What's `cost(append)`? Really good answer though, looks at it from a different angle rather than just statistics. Commented Aug 20, 2013 at 14:16
• `Where` does not create anything, just return one element at the time from `source` sequence if only it fill the predicate. Commented Aug 20, 2013 at 16:30
• @Spoike - Expressions trees are not relevant here, because this is linq-to-objects, not linq-to-something-else (Entity, for example). That's the difference between `IEnumerable.Select(IEnumerable, Func)` and `IQueryable.Select(IQueryable, Expression<Func>)`. You are right that LINQ does "nothing" until you iterate over the collection, which is probably what you meant.
– Kobi
Commented Aug 20, 2013 at 20:51

Here's an in-depth explanation of what's causing the timing-differences.

The `Sum()` function for `IEnumerable<int>` looks like this:

``````public static int Sum(this IEnumerable<int> source)
{
int sum = 0;
foreach(int item in source)
{
sum += item;
}
return sum;
}
``````

In C#, `foreach` is just syntactic sugar for .Net's version of an iterator, `IEnumerator<T>` (not to be confused with `IEnumerable<T>`). So the above code is actually translated to this:

``````public static int Sum(this IEnumerable<int> source)
{
int sum = 0;

IEnumerator<int> iterator = source.GetEnumerator();
while(iterator.MoveNext())
{
int item = iterator.Current;
sum += item;
}
return sum;
}
``````

Remember, the two lines of code you're comparing are the following

``````int result1 = myCollection.Where(mc => mc.IsValid).Sum(mc => mc.Value);
int result2 = myCollection.Sum(mc => mc.IsValid ? mc.Value : 0);
``````

Now here's the kicker:

LINQ uses deferred execution. Thus, while it may appear that `result1` iterates over the collection twice, it actually only iterates over it once. The `Where()` condition is actually applied during the `Sum()`, inside of the call to `MoveNext()` (This is possible thanks to the magic of `yield return`).

This means that, for `result1`, the code inside of the `while` loop,

``````{
int item = iterator.Current;
sum += item;
}
``````

is only executed once for each item with `mc.IsValid == true`. By comparison, `result2` will execute that code for every item in the collection. That is why `result1` is generally faster.

(Though, note that calling the `Where()` condition within `MoveNext()` still has some small overhead, so if most/all of the items have `mc.IsValid == true`, `result2` will actually be faster!)

Hopefully now it's clear why `result2` is usually slower. Now I'd like to explain why I stated in the comments that these LINQ performance comparisons don't matter.

Creating a LINQ expression is cheap. Calling delegate functions is cheap. Allocating and looping over an iterator is cheap. But it's even cheaper to not do these things. Thus, if you find that a LINQ statement is the bottleneck in your program, in my experience rewriting it without LINQ will always make it faster than any of the various LINQ methods.

So, your LINQ workflow should look like this:

1. Use LINQ everywhere.
2. Profile.
3. If the profiler says LINQ is the cause of a bottleneck, rewrite that piece of code without LINQ.

Fortunately, LINQ bottlenecks are rare. Heck, bottlenecks are rare. I've written hundreds of LINQ statements in the last few years, and have ended up replacing <1%. And most of those were due to LINQ2EF's poor SQL optimization, rather than being LINQ's fault.

So, like always, write clear and sensible code first, and wait until after you've profiled to worry about micro-optimizations.

• Small addendum: the top answer has been fixed. Commented Aug 20, 2013 at 20:58

Funny thing. Do you know how is `Sum(this IEnumerable<TSource> source, Func<TSource, int> selector)` defined? It uses `Select` method!

``````public static int Sum<TSource>(this IEnumerable<TSource> source, Func<TSource, int> selector)
{
return source.Select(selector).Sum();
}
``````

So actually, it all should work nearly the same. I did quick research on my own, and here are the results:

``````Where -- mod: 1 result: 0, time: 371 ms
WhereSelect -- mod: 1  result: 0, time: 356 ms
Select -- mod: 1  result 0, time: 366 ms
Sum -- mod: 1  result: 0, time: 363 ms
-------------
Where -- mod: 2 result: 4999999, time: 469 ms
WhereSelect -- mod: 2  result: 4999999, time: 429 ms
Select -- mod: 2  result 4999999, time: 362 ms
Sum -- mod: 2  result: 4999999, time: 358 ms
-------------
Where -- mod: 3 result: 9999999, time: 441 ms
WhereSelect -- mod: 3  result: 9999999, time: 452 ms
Select -- mod: 3  result 9999999, time: 371 ms
Sum -- mod: 3  result: 9999999, time: 380 ms
-------------
Where -- mod: 4 result: 7500000, time: 571 ms
WhereSelect -- mod: 4  result: 7500000, time: 501 ms
Select -- mod: 4  result 7500000, time: 406 ms
Sum -- mod: 4  result: 7500000, time: 397 ms
-------------
Where -- mod: 5 result: 7999999, time: 490 ms
WhereSelect -- mod: 5  result: 7999999, time: 477 ms
Select -- mod: 5  result 7999999, time: 397 ms
Sum -- mod: 5  result: 7999999, time: 394 ms
-------------
Where -- mod: 6 result: 9999999, time: 488 ms
WhereSelect -- mod: 6  result: 9999999, time: 480 ms
Select -- mod: 6  result 9999999, time: 391 ms
Sum -- mod: 6  result: 9999999, time: 387 ms
-------------
Where -- mod: 7 result: 8571428, time: 489 ms
WhereSelect -- mod: 7  result: 8571428, time: 486 ms
Select -- mod: 7  result 8571428, time: 384 ms
Sum -- mod: 7  result: 8571428, time: 381 ms
-------------
Where -- mod: 8 result: 8749999, time: 494 ms
WhereSelect -- mod: 8  result: 8749999, time: 488 ms
Select -- mod: 8  result 8749999, time: 386 ms
Sum -- mod: 8  result: 8749999, time: 373 ms
-------------
Where -- mod: 9 result: 9999999, time: 497 ms
WhereSelect -- mod: 9  result: 9999999, time: 494 ms
Select -- mod: 9  result 9999999, time: 386 ms
Sum -- mod: 9  result: 9999999, time: 371 ms
``````

For following implementations:

``````result = source.Where(x => x.IsValid).Sum(x => x.Value);
result = source.Select(x => x.IsValid ? x.Value : 0).Sum();
result = source.Sum(x => x.IsValid ? x.Value : 0);
result = source.Where(x => x.IsValid).Select(x => x.Value).Sum();
``````

`mod` means: every 1 from `mod` items is invalid: for `mod == 1` every item is invalid, for `mod == 2` odd items are invalid, etc. Collection contains `10000000` items.

And results for collection with `100000000` items:

As you can see, `Select` and `Sum` results are quite consistent across all `mod` values. However `where` and `where`+`select` are not.

• It's very interesting that in your results, all methods starts at the same place and diverge, whereas the It'sNotALie's results cross in the middle. Commented Aug 20, 2013 at 20:41

My guess is that the version with Where filters out the 0s and they are not a subject for Sum (i.e. you are not executing the addition). This is of course a guess since I cannot explain how executing additional lambda expression and calling multiple methods outperforms a simple addition of a 0.

A friend of mine suggested that the fact that the 0 in the sum may cause severe performance penalty because of overflow checks. It would be interesting to see how this would perform in unchecked context.

• Some tests with `unchecked` makes it a tiny, tiny bit better for the `Select`. Commented Aug 20, 2013 at 10:43
• Can someone say if unchecked affects the methods being called down the stack or only the top level operations? Commented Aug 20, 2013 at 11:13
• @Stilgar It only applies to top level. Commented Aug 20, 2013 at 11:30
• So maybe we need to implement unchecked Sum and try it this way. Commented Aug 20, 2013 at 11:36

Running the following sample, it becomes clear to me that the only time Where+Select can outperform Select is in fact when it is discarding a good amount (approx half in my informal tests) of the potential items in the list. In the small example below, I get roughly the same numbers out of both samples when the Where skips approx 4mil items out of 10mil. I ran in release, and reordered the execution of where+select vs select with same results.

``````static void Main(string[] args)
{
int total = 10000000;
Random r = new Random();
var list = Enumerable.Range(0, total).Select(i => r.Next(0, 5)).ToList();
for (int i = 0; i < 4000000; i++)
list[i] = 10;

var sw = new Stopwatch();
sw.Start();

int sum = 0;

sum = list.Where(i => i < 10).Select(i => i).Sum();

sw.Stop();
Console.WriteLine(sw.ElapsedMilliseconds);

sw.Reset();
sw.Start();
sum = list.Select(i => i).Sum();

sw.Stop();

Console.WriteLine(sw.ElapsedMilliseconds);
}
``````
• Mightn't that be because you don't discard the under-tens in the `Select`? Commented Aug 20, 2013 at 10:41
• Running in debug is useless. Commented Aug 20, 2013 at 10:43
• @MarcinJuraszek Obviously. Really meant to say that I ran in release :) Commented Aug 20, 2013 at 10:46
• @It'sNotALie That's the point. It seems to me that the only way Where+Select can outperform Select is when Where is filtering out a large amount of the items being summed. Commented Aug 20, 2013 at 10:47
• That's basically what my question's stating. They tie at about 60%, like this sample does. The question is why, which isn't answered here. Commented Aug 20, 2013 at 10:57

If you need speed, just doing a straightforward loop is probably your best bet. And doing `for` tends to be better than `foreach` (assuming your collection is random-access of course).

Here are the timings I got with 10% of elements being invalid:

``````Where + Select + Sum:   257
Select + Sum:           253
foreach:                111
for:                    61
``````

And with 90% invalid elements:

``````Where + Select + Sum:   177
Select + Sum:           247
foreach:                105
for:                    58
``````

And here is my benchmark code...

``````public class MyClass {
public int Value { get; set; }
public bool IsValid { get; set; }
}

class Program {

static void Main(string[] args) {

const int count = 10000000;
const int percentageInvalid = 90;

var rnd = new Random();
var myCollection = new List<MyClass>(count);
for (int i = 0; i < count; ++i) {
new MyClass {
Value = rnd.Next(0, 50),
IsValid = rnd.Next(0, 100) > percentageInvalid
}
);
}

var sw = new Stopwatch();
sw.Restart();
int result1 = myCollection.Where(mc => mc.IsValid).Select(mc => mc.Value).Sum();
sw.Stop();
Console.WriteLine("Where + Select + Sum:\t{0}", sw.ElapsedMilliseconds);

sw.Restart();
int result2 = myCollection.Select(mc => mc.IsValid ? mc.Value : 0).Sum();
sw.Stop();
Console.WriteLine("Select + Sum:\t\t{0}", sw.ElapsedMilliseconds);
Debug.Assert(result1 == result2);

sw.Restart();
int result3 = 0;
foreach (var mc in myCollection) {
if (mc.IsValid)
result3 += mc.Value;
}
sw.Stop();
Console.WriteLine("foreach:\t\t{0}", sw.ElapsedMilliseconds);
Debug.Assert(result1 == result3);

sw.Restart();
int result4 = 0;
for (int i = 0; i < myCollection.Count; ++i) {
var mc = myCollection[i];
if (mc.IsValid)
result4 += mc.Value;
}
sw.Stop();
Console.WriteLine("for:\t\t\t{0}", sw.ElapsedMilliseconds);
Debug.Assert(result1 == result4);

}

}
``````

BTW, I concur with the Stilgar's guess: the relative speeds of your two cases vary depending on percentage of invalid items, simply because the amount of job `Sum` needs to do varies in the "Where" case.

Rather than try to explain via description, I'm going to take a more mathematical approach.

Given the code below which should approximate what LINQ is doing internally, the relative costs are as follows:
Select only: `Nd + Na`
Where+Select : `Nd + Md + Ma`

To figure out the point where they will cross, we need to do a little algebra:
`Nd + Md + Ma = Nd + Na => M(d + a) = Na => (M/N) = a/(d+a)`

What this means is that in order for the inflection point to be at 50%, the cost of a delegate invocation must be roughly the same as the cost of an addition. Since we know that the actual inflection point was at about 60%, we can work backwards and determine that the cost of a delegate invocation for @It'sNotALie was actually about 2/3 the cost of an addition which is surprising, but that's what his numbers say.

``````static void Main(string[] args)
{
var set = Enumerable.Range(1, 10000000)
.Select(i => new MyClass {Value = i, IsValid = i%2 == 0})
.ToList();

Func<MyClass, int> select = i => i.IsValid ? i.Value : 0;
Console.WriteLine(
Select(set, select)));  // Cost: N delegate
// Total cost: N * (delegate + addition) = Nd + Na

Func<MyClass, bool> where = i => i.IsValid;
Func<MyClass, int> wSelect = i => i.Value;
Console.WriteLine(
Select(                 // Cost: M delegate
Where(set, where),  // Cost: N delegate
wSelect)));
// Total cost: N * delegate + M * (delegate + addition) = Nd + Md + Ma
}

// Cost: N delegate calls
static IEnumerable<T> Where<T>(IEnumerable<T> set, Func<T, bool> predicate)
{
foreach (var mc in set)
{
if (predicate(mc))
{
yield return mc;
}
}
}

// Cost: N delegate calls
static IEnumerable<int> Select<T>(IEnumerable<T> set, Func<T, int> selector)
{
foreach (var mc in set)
{
yield return selector(mc);
}
}

static int Sum(IEnumerable<int> set)
{
unchecked
{
var sum = 0;
foreach (var i in set)
{
sum += i;
}

return sum;
}
}
``````

I think it's interesting that MarcinJuraszek's result is different from It'sNotALie's. In particular, MarcinJuraszek's results start out with all four implementations at the same place, while It'sNotALie's results cross over around the middle. I will explain how this works from the source.

Let us assume that there are `n` total elements, and `m` valid elements.

The `Sum` function is pretty simple. It just loops through the enumerator: http://typedescriptor.net/browse/members/367300-System.Linq.Enumerable.Sum(IEnumerable%601)

For simplicity, let's assume the collection is a list. The both Select and WhereSelect will create a `WhereSelectListIterator`. This means that the actual iterators generated are the same. In both cases, there is a `Sum` that loops over an iterator, the `WhereSelectListIterator`. The most interesting part of the iterator is the MoveNext method.

Since the iterators are the same, the loops are the same. The only difference is in the body of the loops.

The body of these lambdas have very similar cost. The where clause returns a field value, and the ternary predicate also returns a field value. The select clause returns a field value, and the two branches of the ternary operator return either a field value or a constant. The combined select clause has the branch as a ternary operator, but the WhereSelect uses the branch in `MoveNext`.

However, all of these operations are fairly cheap. The most expensive operation so far is the branch, where a wrong prediction will cost us.

Another expensive operation here is the `Invoke`. Invoking a function takes quite a bit longer than adding a value, as Branko Dimitrijevic has shown.

Also weighing in is the checked accumulation in `Sum`. If the processor does not have an arithmetic overflow flag, then this could be costly to check as well.

Hence, the interesting costs are: is:

1. (`n` + `m`) * Invoke + `m` * `checked+=`
2. `n` * Invoke + `n` * `checked+=`

Thus, if the cost of Invoke is much higher than the cost of checked accumulation, then the case 2 is always better. If they're about even, then we will see a balance when about half of the elements are valid.

It looks like on MarcinJuraszek's system, checked+= has negligible cost, but on It'sNotALie's and Branko Dimitrijevic's systems, checked+= has significant costs. It looks like it's the most expensive on It'sNotALie's system since the break even point is much higher. It doesn't look like anyone has posted results from a system where the accumulation costs much more than the Invoke.

• @It'sNotALie. I don't think anyone has a wrong result. I just couldn't explain some things. I had assumed that the cost of Invoke is much higer than that of +=, but it's conceivable that they could be much closer depending on the hardware optimizations. Commented Aug 21, 2013 at 15:21