18

Suppose I have an IEnumerable<X> where some instances of X can be converted to Y, while some cannot, and want an IEnumerable<Y>, containing only those Xes that could be converted to Y.

For example, if I have an IEnumerable<int?> containing both null and non-null values, I might want an IEnumerable<int> containing only the non-null values.

NOTE: please do not take the example of int? too literally; the solution should work with any X and Y, where the difference between X and Y is not just a type difference or a nullability difference.

One way I could do it is as follows:

public static void Main( string[] args )
{
    int?[] a = { null, 42, null, 5 };
    IEnumerable<int> ints = a //
            .Where( i => i.HasValue ) //
            .Select( i => i!.Value );
    foreach( var i in ints )
        Console.WriteLine( i );
    Console.ReadLine();
}

While the code above works, I would like to combine Select() and Where() in one statement. Doing so would make the code terser, and neater as well, by avoiding that ugly i!. It would also do both conversion and filtering in one step, thus taking advantage of work done during filtering to lessen the amount of work necessary during conversion.

Is there a way to achieve that?

1
  • In my personal code base, I wrote my own extension method, WhereNotNull<T> that takes an IEnumerable<T?> and returns an IEnumerable<T>. It works for nullable reference types and Nullable<T> value types.
    – Cole Tobin
    Mar 28, 2023 at 18:31

3 Answers 3

17

General Case

You can write your own extension method that combines Select and Where:

public static IEnumerable<TResult> SelectWhere<TSource, TResult>(
    this IEnumerable<TSource> source, Func<TSource, (bool, TResult)> selector) 
{
    foreach (TSource item in source)
        if (selector(item) is (true, var result))
            yield return result;
}

For each input value, the selector should return (true, transformedValue) if the value should be included or (false, default) if the value should be excluded.

As an example, given an array int?[] a, the statement

IEnumerable<int> negatedInts = a
    .Where(i => i.HasValue)
    .Select(i => -i!.Value);

can be rewritten like this:

IEnumerable<int> negatedInts = a
    .SelectWhere(i => i is int value ? (true, -value) : (false, default));

Special Case: Filtering by Type

If you simply want to filter values by type without otherwise transforming the values, then you can use the LINQ OfType method:

  • If you have an IEnumerable<int?>, then .OfType<int>() returns IEnumerable<int> and excludes null values.
  • If you have an IEnumerable<Base>, then .OfType<Derived>() returns IEnumerable<Derived> and excludes null references and objects of other types.
1
  • Very interesting approach! However, I think this might be a bit of an anti-pattern and could lead later to unwanted results if used wrongly. But still a very good perspective. Feb 20 at 13:19
7

It can be done in one step using LINQ's SelectMany method, e.g.:

IEnumerable<int> ints = a
    .SelectMany(e => e switch
    {
        int i => new[] { i },
        _ => Enumerable.Empty<int>()
    });

This works because SelectMany allows us to create a new sequence of elements (possible of a different type) for every element of the input sequence (which then are simply concatenated by SelectMany to produce the final result). Here we return a single-element sequence for every element we want to include and empty sequence for every element we want to discard.

For fun, if we go a bit deeper into theory, LINQ is an example of monad with SelectMany serving the role of monad's bind operation (>>= operator in Haskell). Which means that in fact we should be able to implement all LINQ's methods using only SelectMany method.

NB: The above implementation might not be the most efficient way to do it since we allocate a new single-element array for every element we want to include in the resulting sequence. And in fact that new[] { i } expression if monad's return operator for which there is no corresponding method in LINQ. We can implement it ourselves easily though (just for fun):

public static class EnumerableExtension
{
    public static IEnumerable<T> Return<T>(this T elem)
    {
        yield return elem;
    }
}

This Return might even improve the efficiency of our implementation:

IEnumerable<int> ints = a
    .SelectMany(e => e switch
    {
        int i => i.Return(),
        _ => Enumerable.Empty<int>()
    });

Or without extension method:

IEnumerable<int> ints = a
    .SelectMany(e => e switch
    {
        int i => Enumerable.Empty<int>().Prepend(i),
        _ => Enumerable.Empty<int>()
    });

Update:

After @MichaelLiu comment I run a quick benchmark which demonstrated that contrary to my expectations new[] { i } was indeed more efficient than Return both in terms of memory and performance while both original approach and SelectWhere were much more efficient than anything else I tried (especially in terms of memory allocation):

Method Mean Error StdDev Gen0 Allocated
Original 9.462 μs 0.0094 μs 0.0078 μs 0.0153 104 B
SelectWhere 9.963 μs 0.0486 μs 0.0379 μs 0.0153 104 B
Array 17.547 μs 0.0465 μs 0.0412 μs 5.0964 32096 B
Return 31.306 μs 0.0816 μs 0.0681 μs 6.3477 40096 B
Prepend 26.489 μs 0.1392 μs 0.1162 μs 8.9417 56096 B
Append 26.555 μs 0.0728 μs 0.0681 μs 8.9417 56096 B
3
  • 2
    Note that in current implementations of the C# compiler, the Return extension method allocates an enumerator object on each call, so it isn't necessarily more efficient than simply writing new[] { i }. Mar 26, 2023 at 16:22
  • @MichaelLiu It seems that when array is actually enumerated an ArrayEnumerator is also allocated (in addition to array allocation) so I still expect array to be worse at least in terms of memory allocation. But it should probably be benchmarked to be sure.
    – Ed'ka
    Mar 27, 2023 at 2:56
  • @MichaelLiu Yes, you were right: the actual benchmarks demonstrated that I was wrong in my expectations: new[] { i } is indeed more efficient that Return. I updated my answer with benchmark results. I have yet to understand why this is the case though.
    – Ed'ka
    Mar 27, 2023 at 4:53
2

With pattern matching we can write:

int i = 0;
IEnumerable<int> ints = a
    .Where(n => n is { } temp && (i = temp) is var _)
    .Select(_ => i);

Where n is { } temp is an empty property pattern which implicitly tests for not null and assigns the int to temp.

In C# an assignment can be used as an expression where the assigned value is the result of this expression. This result is discarded later in the var-pattern which always evaluates to true.

This is not something I would use production code, however. The original code of the OP is totally okay. This i!.Value is not very beautiful, but that's why the ! has been introduced after all.

1
  • 1
    Agreed, the original is more readable and in production code, unless your building something extremely performance sensitive, always go for the more readable. Mar 30, 2023 at 22:16

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