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This is a follow up to my previous question regarding the Seq module's iter and map functions being much slower compared to the Array and List module equivalents.

Looking at the source, I can see that some functions such as isEmpty and length performs a very simple type check to optimize for arrays and lists before resorting to using IEnumerator.

[<CompiledName("IsEmpty")>]
let isEmpty (source : seq<'T>)  = 
    checkNonNull "source" source
    match source with 
    | :? ('T[]) as a -> a.Length = 0
    | :? list<'T> as a -> a.IsEmpty
    | :? ICollection<'T> as a -> a.Count = 0
    | _ -> 
        use ie = source.GetEnumerator()
        not (ie.MoveNext())

[<CompiledName("Length")>]
let length (source : seq<'T>)    = 
    checkNonNull "source" source
    match source with 
    | :? ('T[]) as a -> a.Length
    | :? ('T list) as a -> a.Length
    | :? ICollection<'T> as a -> a.Count
    | _ -> 
        use e = source.GetEnumerator() 
        let mutable state = 0 
        while e.MoveNext() do
            state <-  state + 1;
        state

In the case of the iter the same approach can be done to vastly improve its performance, when I shadowed the iter function it presented significant gains over the built-in version:

[<CompiledName("Iterate")>]
let iter f (source : seq<'T>) = 
    checkNonNull "source" source
    use e = source.GetEnumerator()
    while e.MoveNext() do
        f e.Current;

My question is, given that some of the functions in the Seq module were optimized for use with specific collection types (arrays, list< T>, etc.) how come other functions such as iter and nth were not optimized in a similar way?

Also, in the case of map function, as @mausch pointed out, is it not possible to employ a similar approach to Enumerable.Select (see below) and build up specialized iterators for different collection types?

public static IEnumerable<TResult> Select<TSource, TResult>(this IEnumerable<TSource> source, Func<TSource, TResult> selector)
    {
      if (source == null)
        throw Error.ArgumentNull("source");
      if (selector == null)
        throw Error.ArgumentNull("selector");
      if (source is Enumerable.Iterator<TSource>)
        return ((Enumerable.Iterator<TSource>) source).Select<TResult>(selector);
      if (source is TSource[])
        return (IEnumerable<TResult>) new Enumerable.WhereSelectArrayIterator<TSource, TResult>((TSource[]) source, (Func<TSource, bool>) null, selector);
      if (source is List<TSource>)
        return (IEnumerable<TResult>) new Enumerable.WhereSelectListIterator<TSource, TResult>((List<TSource>) source, (Func<TSource, bool>) null, selector);
      else
        return (IEnumerable<TResult>) new Enumerable.WhereSelectEnumerableIterator<TSource, TResult>(source, (Func<TSource, bool>) null, selector);
    }

Many thanks in advance.

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3  
I'm not sure you'll get a decent answer to a 'why' question like this here; my best guess is simply lack of developer time. –  ildjarn Jun 4 '12 at 22:09

2 Answers 2

In the case of the iter the same approach can be done to vastly improve its performance

I think this is where the answer to your question is. Your test is artificial, and doesn't actually test any real world examples of these methods. You tested 10,000,000 iterations of these methods in order to get differences in timing in ms.

Converted back to per item costs, here they are:

          Array   List
Seq.iter   4 ns    7 ns
Seq.map   20 ns   91 ns

These methods are typically used once per collection, meaning this cost is an additional linear factor to your algorithms performance. In the worst case you are losing less than 100 ns per item in a list (which you shouldn't be using if you care about performance that much).

Contrast this with the case of length which is always linear in the general case. By adding this optimization you provide enormous benefit to someone who forgot to manually cache the length but luckily is always given a list.

Similarly you may call isEmpty many times, and adding another object creation is silly if you can just ask directly. (This one isn't as strong an argument)

Another thing to keep in mind is that neither of those methods actually looks at more than one element of the output. What would you expect the following code to do (excluding syntax errors or missing methods)

type Custom() =
  interface IEnumerable with
    member x.GetEnumerator() =
      return seq {
        yield 1
        yield 2
      }
  interface IList with
    member x.Item with
      get(index) = index
    member x.Count = 12

 let a = Custom()
 a |> Seq.iter (v -> printfn (v.ToString()))
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1  
Your example demonstrates why I consider this a misfeature. It follows the principle of least surprise that Seq only depends on seq<_>, Array on arrays, and List on list<_>. It's up to the programmer to choose which interface should be used. –  Daniel Jun 5 '12 at 18:26
1  
@Daniel: It is an implementation detail to improve performance. BTW, the F# implementation doesn't depend on IList, only on list, which can't be overloaded to create these weird situations. –  Guvante Jun 5 '12 at 22:37
1  
Wouldn't you expect the two to be the same? The possibility that they could differ seems bizarre. But this is getting off point. If a method accepts a value of type 'T, I expect it to interact with it only as a 'T, not repeatedly downcast, fishing for a more concrete type to use. It would be a tenable approach, given that let-bound functions can't be overloaded, if more precisely typed versions didn't exist. –  Daniel Jun 6 '12 at 16:48
1  
@Daniel: It is an implementation detail that can provide significant performance enhancements, and only becomes a problem when you break well defined standards. I can't possibly find a way to justify removing it other than from a purity standpoint. When righting software changing an implementation detail purely for purity reasons is not a good idea. –  Guvante Jun 6 '12 at 19:00
1  
I agree with you (and will rest my case here :-)). My point is the question assumes this kind of optimization is generally desirable. While it may be occasionally worthwhile it hardly seems like a pattern that should be broadly applied. –  Daniel Jun 6 '12 at 19:30

On the surface, the type-checks in Seq.length/isEmpty seem like mistakes. I assume most Seq functions don't perform such checks for orthogonality: type-specific versions already exist in the List/Array modules. Why duplicate them?

Those checks make more sense in LINQ since it only uses IEnumerable directly.

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5  
At least in the case of Seq.length, the optimization can potentially turn an O(n) operation into an O(1) operation. I doubt this is a mistake. –  kvb Jun 4 '12 at 22:27
    
@kvb: That merely emphasizes the OP's point. Can you answer his question? If you think those are valid optimizations (in spite of available type-specific alternatives) why not apply them to other functions? They seem unnecessary and redundant to me. –  Daniel Jun 5 '12 at 4:09
4  
No, I don't know the answer, but in the case of Seq.iter, Seq.map, etc. doing a type test wouldn't change the asymptotic complexity of the algorithm, just the constant factors. –  kvb Jun 5 '12 at 9:58
2  
It depends on what kind of input you are expecting. If you are taking in a seq from an external source (say a library) then you would want those enhancements, for the same reason that LINQ does. –  Guvante Jun 5 '12 at 17:15
    
@kvb: My contention isn't that these are bad optimizations. I'm merely arguing that their presence in isEmpty/length is less consistent and warrants more justification than their absence from other functions. –  Daniel Jun 5 '12 at 18:22

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