# Speeding up a repeated function call

I'm trying to calculate the following value:

``````1/N * sum[i=0 to N-1]( log(abs(r_i - 2 * r_i * x_i)) )
``````

where x_i is recursively calculated with:

``````x_{i+1} = r_i * x_i * (1 - x_i)
``````

Where all the `r_i`s are given (although they change with `i`), and `x_0` is given. (As far as I can tell there is no tricky mathematical way to simplify this calculation to a non-iterative formula to speed it up like that).

My problem is that it is very slow, and I wonder if some outside perspective could help me speed it up.

``````# x0: a scalar. rs: a numeric vector, length N
# N: typically ~5000
f <- function (x0, rs, N) {
lambda <- 0
x <- x0
for (i in 1:N) {
r <- rs[i]
rx <- r * x
lambda <- lambda + log(abs(r - 2 * rx))
# calculate the next x value
x <- rx - rx * x
}
return(lambda / N)
}
``````

Now on its own this function is decently fast, but I would like to be calling it ~ 4,000,000 times (once for each cell in a 2000 by 2000 matrix), each with a different `rs` vector.

But if I call it even just 2500 times (with N=1000), it takes ~25 seconds, with the following profile:

``````      self.time self.pct total.time total.pct
"f"       19.98    81.22      24.60    100.00
"*"        2.00     8.13       2.00      8.13
"-"        1.32     5.37       1.32      5.37
"+"        0.70     2.85       0.70      2.85
"abs"      0.56     2.28       0.56      2.28
":"        0.04     0.16       0.04      0.16
``````

Does anyone know how I might speed this up? Looks like multiplication takes a while, but I've already pre-cached any multiplication that is repeated.

I also tried taking advantage that `sum( log(stuff(i)) )` is the same as `log(prod(stuff(i))` to reduce the calls to `log` and `abs`, but this turned out unfeasable as `stuff` was a vector of length `N` (in the thousands) and typical values at least 1, so `prod(stuff)` ended up being `Inf` to R.

In my opinion, the bottleneck is the `for` loop in your function.

I rewrite it with Rcpp as follow:

``````# x0: a scalar. rs: a numeric vector, length N
# N: typically ~5000
x0 <- runif(1)
N <- 5000
rs <- rnorm(5000)
f <- function (x0, rs, N) {
lambda <- 0
x <- x0
for (i in 1:N) {
r <- rs[i]
rx <- r * x
lambda <- lambda + log(abs(r - 2 * rx))
# calculate the next x value
x <- rx - rx * x
}
return(lambda / N)
}

library(inline)
library(Rcpp)
f1 <- cxxfunction(sig=c(Rx0="numeric", Rrs="numeric"), plugin="Rcpp", body='
double x0 = as<double>(Rx0);
NumericVector rs(Rrs);
int N = rs.size();
double lambda = 0, x = x0, r, rx;
for(int i = 0;i < N;i++) {
r = rs[i];
rx = r * x;
lambda = lambda + log( fabs(r - 2 * rx) );
x = rx - rx * x;
}
lambda /= N;
return wrap(lambda);
')
f(x0, rs, N)
f1(x0, rs)

library(rbenchmark)

benchmark(f(x0, rs, N), f1(x0, rs))
``````

`f1` is 140 times faster than `f` on my last test.

• Ahhh, Rcpp, I should really start learning you...cheers! – mathematical.coffee Jan 24 '13 at 23:58