That just provided a nice opportunity to plug Rcpp which allows us to add C++ functions easily to R.

So after fixing your code slightly, and using the packages inline (to easily compile, load and link short code snippets as dynamically loadable functions) as well as rbenchmark to time and compare functions, we end up with a **stunning** 700-fold increase in performance:

```
R> print(res)
test replications elapsed relative user.self sys.self
2 fibRcpp(N) 1 0.092 1.000 0.10 0
1 fibR(N) 1 65.693 714.054 65.66 0
R>
```

Here we see elapsed times of 92 milliseonds versus 65 seconds, for a relative ratio of 714. But by now everybody else told you not to do this directly in R.... The code is below.

```
## inline to compile, load and link the C++ code
require(inline)
## we need a pure C/C++ function as the generated function
## will have a random identifier at the C++ level preventing
## us from direct recursive calls
incltxt <- '
int fibonacci(const int x) {
if (x == 0) return(0);
if (x == 1) return(1);
return (fibonacci(x - 1)) + fibonacci(x - 2);
}'
## now use the snipped above as well as one argument conversion
## in as well as out to provide Fibonacci numbers via C++
fibRcpp <- cxxfunction(signature(xs="int"),
plugin="Rcpp",
incl=incltxt,
body='
int x = Rcpp::as<int>(xs);
return Rcpp::wrap( fibonacci(x) );
')
## for comparison, the original (but repaired with 0/1 offsets)
fibR <- function(seq) {
if (seq == 0) return(0);
if (seq == 1) return(1);
return (fibR(seq - 1) + fibR(seq - 2));
}
## load rbenchmark to compare
library(rbenchmark)
N <- 35 ## same parameter as original post
res <- benchmark(fibR(N),
fibRcpp(N),
columns=c("test", "replications", "elapsed",
"relative", "user.self", "sys.self"),
order="relative",
replications=1)
print(res) ## show result
```

And for completeness, the functions also produce the correct output:

```
R> sapply(1:10, fibR)
[1] 1 1 2 3 5 8 13 21 34 55
R> sapply(1:10, fibRcpp)
[1] 1 1 2 3 5 8 13 21 34 55
R>
```

`1,2,3,5,8,...`

whereas the correct sequence is`0,1,1,2,3,5,8,...`

?`gmp`

has the function`fibnum`

, to compute fibonacci numbers in arbitrary precision. With the standard`doubles`

you can get only up to`n=55`

or so.