I am digging into F# source code recently.

in Seq.fs:

```
// Binding.
//
// We use a type defintion to apply a local dynamic optimization.
// We automatically right-associate binding, i.e. push the continuations to the right.
// That is, bindG (bindG G1 cont1) cont2 --> bindG G1 (cont1 o cont2)
// This makes constructs such as the following linear rather than quadratic:
//
// let rec rwalk n = { if n > 0 then
// yield! rwalk (n-1)
// yield n }
```

After seeing the above code, I tested two code:

```
let rec rwalk n = seq { if n > 0 then
yield n
yield! rwalk (n-1)
}
```

and

```
let rec rwalk n = seq { if n > 0 then
yield! rwalk (n-1)
yield n
}
```

I found the first one is very fast, while the second is very slow. If n = 10000, it costs 3 seconds on my machine to generate this sequence, thus quadratic time.

The quadratic time is reasonable, as e.g.

`seq { yield! {1; 2; ...; n-1}; yield n }`

translates to

```
Seq.append {1; 2; ...; n-1} {n}
```

This append operation should take linear time, I guess. While in the first code, the append operation is like this: `seq { yield n; yield! {n-1; n-2; ...; 1} }`

, which costs constant time.

The the comments in code say that it is `linear`

(maybe this linear is not linear time). Maybe this `linear`

relates to using customized implementation for sequence rather than Moand/F# computation expression (as mentioned in F# specification, however the specification does not mention the reason for doing so...).

Could anyone clarify the fuzziness here? Thanks a lot!

(p.s. because this is a language design and optimization problem, I also attached Haskell tag to see if people there have insights. )