I turned this 'inside-out' by creating a vector x where the ith element is the value after each iteration of the algorithm. The result is relatively intelligible as

```
f1 <- function(L) {
x <- seq_len(L)
count <- integer(L)
while (any(i <- x > 1)) {
count[i] <- count[i] + 1L
x <- ifelse(round(x/2) == x/2, x / 2, 3 * x + 1) * i
}
count
}
```

This can be optimized to (a) track only those values still in play (via idx) and (b) avoid unnecessary operations, e.g., ifelse evaluates both arguments for all values of x, x/2 evaluated twice.

```
f2 <- function(L) {
idx <- x <- seq_len(L)
count <- integer(L)
while (length(x)) {
ix <- x > 1
x <- x[ix]
idx <- idx[ix]
count[idx] <- count[idx] + 1L
i <- as.logical(x %% 2)
x[i] <- 3 * x[i] + 1
i <- !i
x[i] <- x[i] / 2
}
count
}
```

with f0 the original function, I have

```
> L <- 10000
> system.time(ans0 <- f0(L))
user system elapsed
7.785 0.000 7.812
> system.time(ans1 <- f1(L))
user system elapsed
1.738 0.000 1.741
> identical(ans0, ans1)
[1] TRUE
> system.time(ans2 <- f2(L))
user system elapsed
0.301 0.000 0.301
> identical(ans1, ans2)
[1] TRUE
```

A tweak is to update odd values to 3 * x[i] + 1 and then do the division by two unconditionally

```
x[i] <- 3 * x[i] + 1
count[idx[i]] <- count[idx[i]] + 1L
x <- x / 2
count[idx] <- count[idx] + 1
```

With this as f3 (not sure why f2 is slower this morning!) I get

```
> system.time(ans2 <- f2(L))
user system elapsed
0.36 0.00 0.36
> system.time(ans3 <- f3(L))
user system elapsed
0.201 0.003 0.206
> identical(ans2, ans3)
[1] TRUE
```

It seems like larger steps can be taken at the divide-by-two stage, e.g., 8 is 2^3 so we could take 3 steps (add 3 to count) and be finished, 20 is 2^2 * 5 so we could take two steps and enter the next iteration at 5. Implementations?