This is an optimization performed by the F# compiler. As far as I know, it has actually been implemented later - F# compiler first had list comprehensions, then a general-purpose version of computation expressions (also used for `seq { ... }`

) but that was less efficient, so the optimization was added in some later version.

The main reason is that this removes many allocations and indirections. Let's say you have something like:

```
seq { for i in input do
yield i
yield i * 10 }
```

When using computation expressions, this gets translated to something like:

```
seq.Delay(fun () -> seq.For(input, fun i ->
seq.Combine(seq.Yield(i), seq.Delay(fun () -> seq.Yield(i * 10)))))
```

There is a couple of function allocations and the `For`

loop always needs to invoke the lambda function. The optimization turns this into a state machine (similar to the C# state machine), so the `MoveNext()`

operation on the generated enumerator just mutates some state of the class and then returns...

You can easily compare the performance by defining a custom computation builder for sequences:

```
type MSeqBuilder() =
member x.For(en, f) = Seq.collect f en
member x.Yield(v) = Seq.singleton v
member x.Delay(f) = Seq.delay f
member x.Combine(a, b) = Seq.concat [a; b]
let mseq = MSeqBuilder()
let input = [| 1 .. 100 |]
```

Now we can test this (using `#time`

in F# interactive):

```
for i in 0 .. 10000 do
mseq { for x in input do
yield x
yield x * 10 }
|> Seq.length |> ignore
```

On my computer, this takes 2.644sec when using the custom `mseq`

builder but only 0.065sec when using the built-in optimized `seq`

expression. So the optimization makes sequence expressions significantly more efficient.