Performance of seq<int> vs Lazy<LazyList<int>> in F#

There is a well known solution for generating an infinite stream of Hamming numbers (i.e. all positive integers `n` where `n = 2^i * 3^j * 5^k`). I have implemented this in two different ways in F#. The first method uses `seq<int>`. The solution is elegant, but the performance is terrible. The second method uses a custom type where the tail is wrapped in `Lazy<LazyList<int>>`. The solution is clunky, but the performance is amazing.

Can someone explain why the performance using `seq<int>` is so bad and if there is a way to fix it? Thanks.

Method 1 using `seq<int>`.

``````// 2-way merge with deduplication
let rec (-|-) (xs: seq<int>) (ys: seq<int>) =
let xstl = Seq.skip 1 xs
let ystl = Seq.skip 1 ys
if x < y then seq { yield x; yield! xstl -|- ys }
elif x > y then seq { yield y; yield! xs -|- ystl }
else seq { yield x; yield! xstl -|- ystl }

let rec hamming: seq<int> = seq {
yield 1
let xs = Seq.map ((*) 2) hamming
let ys = Seq.map ((*) 3) hamming
let zs = Seq.map ((*) 5) hamming
yield! xs -|- ys -|- zs
}

[<EntryPoint>]
let main argv =
Seq.iter (printf "%d, ") <| Seq.take 100 hamming
0
``````

Method 2 using `Lazy<LazyList<int>>`.

``````type LazyList<'a> = Cons of 'a * Lazy<LazyList<'a>>

// Map `f` over an infinite lazy list
let rec inf_map f (Cons(x, g)) = Cons(f x, lazy(inf_map f (g.Force())))

// 2-way merge with deduplication
let rec (-|-) (Cons(x, f) as xs) (Cons(y, g) as ys) =
if x < y then Cons(x, lazy(f.Force() -|- ys))
elif x > y then Cons(y, lazy(xs -|- g.Force()))
else Cons(x, lazy(f.Force() -|- g.Force()))

let rec hamming =
Cons(1, lazy(let xs = inf_map ((*) 2) hamming
let ys = inf_map ((*) 3) hamming
let zs = inf_map ((*) 5) hamming
xs -|- ys -|- zs))

[<EntryPoint>]
let main args =
let a = ref hamming
let i = ref 0
while !i < 100 do
match !a with
| Cons (x, f) ->
printf "%d, " x
a := f.Force()
i := !i + 1
0
``````
-

Ganesh is right in that you're evaluating the sequence multiple times. `Seq.cache` will help improve performance, but you get much better performance out of `LazyList` because the underlying sequence is only ever evaluated once then cached, so it can be traversed much more rapidly. In fact, this is a good example of where `LazyList` should be used over a normal `seq`.

It also looks like there is some significant overhead introduced by your use of `Seq.map` here. I believe the compiler is allocating a closure each time it's called there. I changed your `seq` based code to use `seq`-expressions there instead, and it's about 1/3 faster than the original for the first 40 numbers in the sequence:

``````let rec hamming: seq<int> = seq {
yield 1
let xs = seq { for x in hamming do yield x * 2 }
let ys = seq { for x in hamming do yield x * 3 }
let zs = seq { for x in hamming do yield x * 5 }
yield! xs -|- ys -|- zs
}
``````

My ExtCore library includes a `lazyList` computation builder which works just like `seq`, so you can simplify your code like this:

``````// 2-way merge with deduplication
let rec (-|-) (xs: LazyList<'T>) (ys: LazyList<'T>) =
let xstl = LazyList.skip 1 xs
let ystl = LazyList.skip 1 ys
if x < y then lazyList { yield x; yield! xstl -|- ys }
elif x > y then lazyList { yield y; yield! xs -|- ystl }
else lazyList { yield x; yield! xstl -|- ystl }

let rec hamming : LazyList<uint64> = lazyList {
yield 1UL
let xs = LazyList.map ((*) 2UL) hamming
let ys = LazyList.map ((*) 3UL) hamming
let zs = LazyList.map ((*) 5UL) hamming
yield! xs -|- ys -|- zs
}

[<EntryPoint>]
let main argv =
let watch = Stopwatch.StartNew ()

hamming
|> LazyList.take 2000
|> LazyList.iter (printf "%d, ")

watch.Stop ()
printfn ""
printfn "Elapsed time: %.4fms" watch.Elapsed.TotalMilliseconds

0   // Return an integer exit code
``````

(NOTE: I also made your `(-|-)` function generic, and modified `hamming` to use 64-bit unsigned ints because 32-bit signed ints overflow after a bit). This code runs through the first 2000 elements of the sequence on my machine in ~450ms; the first 10000 elements takes ~3500ms.

-
I'm surprised that a `seq`-comprehension is so much faster than `Seq.map`. I also tried to get this to work with F# PowerPack, but I haven't been successful so far. – fysx Jul 6 '14 at 21:23
@fysx Use my ExtCore library - it contains an updated (and maintained) version of the `LazyList` code from the F# PowerPack. It also has a `lazyList` builder which greatly simplifies writing this kind of code. – Jack P. Jul 6 '14 at 21:26
@fysx The `seq`-comprehension is usually faster because it can be better optimized by the compiler. `Seq.map` isn't inherently slow, but in this case there's a lot of overhead because the code is repeatedly evaluating the sequence, and the compiled code has to allocate a closure each time `Seq.map` is called. – Jack P. Jul 6 '14 at 21:28
I used the Package Manager Console and 'Install-Package ExtCore'. Without `main`, but only `(-|-)` and `hamming`, I get "This expression was expected to have type `LazyList<'a>` but here has type `LazyList<uint64>`" for `hamming`. I'm using Visual Studio 2013. I tried specifying the types, but generally there's some type mismatch between `lazyList` and `hamming`. Sad. – fysx Jul 6 '14 at 21:45
@fysx That's odd -- I have no problem compiling the code above, even if I comment out `main`. Would you mind opening an issue on the ExtCore github page about this? I'd like to help you solve the problem and it'd be easy to move the discussion there. – Jack P. Jul 6 '14 at 22:00

Your `seq` for `hamming` is re-evaluated from the beginning on each recursive call. `Seq.cache` is some help:

``````let rec hamming: seq<int> =
seq {
yield 1
let xs = Seq.map ((*) 2) hamming
let ys = Seq.map ((*) 3) hamming
let zs = Seq.map ((*) 5) hamming
yield! xs -|- ys -|- zs
} |> Seq.cache
``````

However as you point out the `LazyList` is still much better on large inputs, even if every single sequence is cached.

I'm not entirely certain why they differ by more than a small constant factor, but perhaps it's better to just focus on making the `LazyList` less ugly. Writing something to convert it to a `seq` makes processing it much nicer:

``````module LazyList =
let rec toSeq l =
match l with
| Cons (x, xs) ->
seq {
yield x
yield! toSeq xs.Value
}
``````

You can then use your simple `main` directly. It's also not really necessary to use mutation to process the `LazyList`, you could just do so recursively.

The definition doesn't look so bad though the `lazy` and `Force()` do clutter it up a bit. That looks marginally better if you use `.Value` instead of `.Force()`. You could also define a computation builder for `LazyList` similar to the `seq` one to recover the really nice syntax, though I'm not sure it's worth the effort.

-
Sprinkling `|> Seq.cache` throughout after I use `seq {...}` does improve performance, but not substantially (especially if I compute much larger numbers in the sequence. I noticed stackoverflow.com/questions/9201402/sequence-vs-lazylist, which seems to compliment your suggestion well. – fysx Jul 6 '14 at 20:49
For 1..100 it made it near-instantaneous compared to very slow. What's a typical number where your lazy lists still outperform it substantially? – Ganesh Sittampalam Jul 6 '14 at 20:51
OK, I see it doesn't really work well for 1000 and 10000 is a dead loss even if I put `Seq.cache` on every single sequence. – Ganesh Sittampalam Jul 6 '14 at 20:59
Try 1500. The `LazyList` version should be noticeably faster. – fysx Jul 6 '14 at 20:59
ExtCore includes a `lazyList` computation builder, so you need not build your own :) – Jack P. Jul 6 '14 at 21:10

Here is a sequence base version with better performance.

``````let hamming =
let rec loop nextHs =
seq {
let h = nextHs |> Set.minElement
yield h
yield! nextHs
|> Set.remove h