R: FAST multivariate optimization packages?

I am looking to find a local minimum of a scalar function of 4 variables, and I have range-constraints on the variables ("box constraints"). There's no closed-form for the function derivative, so methods needing an analytical derivative function are out of the question. I've tried several options and control parameters with the `optim` function, but all of them seem very slow. Specifically, they seem to spend a lot of time between calls to my (R-defined) objective function, so I know the bottleneck is not my objective function but the "thinking" between calls to my objective function. I looked at CRAN Task View for optimization and tried several of those options (`DEOptim` from `RcppDE`, etc) but none of them seem any good. I would have liked to try the `nloptr` package (an R wrapper for NLOPT library) but it seems to be unavailable for windows.

I'm wondering, are there any good, fast optimization packages that people use that I may be missing? Ideally these would be in the form of thin wrappers around good C++/Fortran libraries, so there's minimal pure-R code. (Though this shouldn't be relevant, my optimization problem arose while trying to fit a 4-parameter distribution to a set of values, by minimizing a certain goodness-of-fit measure).

In the past I've found R's optimization libraries to be quite slow, and ended up writing a thin R wrapper calling a C++ API of a commercial optimization library. So are the best libraries necessarily commercial ones?

UPDATE. Here is a simplified example of the code I'm looking at:

``````###########
## given a set of values x and a cdf, calculate a measure of "misfit":
## smaller value is better fit
## x is assumed sorted in non-decr order;
Misfit <- function(x, cdf) {
nevals <<- nevals + 1
thinkSecs <<- thinkSecs + ( Sys.time() - snapTime)
cat('S')
if(nevals %% 20 == 0) cat('\n')
L <- length(x)
cdf_x <- pmax(0.0001, pmin(0.9999, cdf(x)))
measure <- -L - (1/L) * sum( (2 * (1:L)-1 )* ( log( cdf_x ) + log( 1 - rev(cdf_x))))
snapTime <<- Sys.time()
cat('E')
return(measure)
}
## Given 3 parameters nu (degrees of freedom, or shape),
## sigma (dispersion), gamma (skewness),
## returns the corresponding 4-parameter student-T cdf parametrized by these params
## (we restrict the location parameter mu to be 0).
skewtGen <- function( p ) {
require(ghyp)
pars = student.t( nu = p[1], mu = 0, sigma = p[2], gamma = p[3] )
function(z) pghyp(z, pars)
}

## Fit using optim() and BFGS method
fit_BFGS <- function(x, init = c()) {
x <- sort(x)
nevals <<- 0
objFun <- function(par) Misfit(x, skewtGen(par))
snapTime <<- Sys.time() ## global time snap shot
thinkSecs <<- 0 ## secs spent "thinking" between objFun calls
tUser <- system.time(
res <- optim(init, objFun,
lower = c(2.1, 0.1, -1), upper = c(15, 2, 1),
method = 'L-BFGS-B',
control = list(trace=2, factr = 1e12, pgtol = .01 )) )[1]
cat('Total time = ', tUser,
' secs, ObjFun Time Pct = ', 100*(1 - thinkSecs/tUser), '\n')
cat('results:\n')
print(res\$par)
}

fit_DE <- function(x) {
x <- sort(x)
nevals <<- 0
objFun <- function(par) Misfit(x, skewtGen(par))
snapTime <<- Sys.time() ## global time snap shot
thinkSecs <<- 0 ## secs spent "thinking" between objFun calls
require(RcppDE)
tUser <- system.time(
res <- DEoptim(objFun,
lower = c(2.1, 0.1, -1),
upper = c(15, 2, 1) )) [1]
cat('Total time = ',             tUser,
' secs, ObjFun Time Pct = ', 100*(1 - thinkSecs/tUser), '\n')
cat('results:\n')
print(res\$par)
}
``````

Let's generate a random sample:

``````set.seed(1)
# generate 1000 standard-student-T points with nu = 4 (degrees of freedom)
x <- rt(1000,4)
``````

First fit using the `fit.tuv` (for "T UniVariate") function in the `ghyp` package -- this uses the Max-likelihood Expectation-Maximization (E-M) method. This is wicked fast!

``````require(ghyp)
> system.time( print(unlist( pars <- coef( fit.tuv(x, silent = TRUE) ))[c(2,4,5,6)]))
nu          mu       sigma       gamma
3.16658356  0.11008948  1.56794166 -0.04734128
user  system elapsed
0.27    0.00    0.27
``````

Now I am trying to fit the distribution a different way: by minimizing the "misfit" measure defined above, using the standard `optim()` function in base R. Note that the results will not in general be the same. My reason for doing this is to compare these two results for a whole class of situations. I pass in the above Max-Likelihood estimate as the starting point for this optimization.

``````> fit_BFGS( x, init = c(pars\$nu, pars\$sigma, pars\$gamma) )
N = 3, M = 5 machine precision = 2.22045e-16
....................
....................
.........
iterations 5
function evaluations 7
segments explored during Cauchy searches 7
active bounds at final generalized Cauchy point 0
norm of the final projected gradient 0.0492174
final function value 0.368136

final  value 0.368136
converged
Total time =  41.02  secs, ObjFun Time Pct =  99.77084
results:
[1] 3.2389296 1.5483393 0.1161706
``````

I also tried to fit with the `DEoptim()` but it ran for too long and I had to kill it. As you can see from the output above, 99.8% of the time is attributable to the objective function! So Dirk and Mike were right in their comments below. I should have more carefully estimated the time spent in my objective function, and printing dots was not a good idea! Also I suspect the MLE(E-M) method is very fast because it uses an analytical (closed-form) for the log-likelihood function.

-
DEoptim and RcppDE essentially wrap a C implementation of the differential evolution algorithm. There is very minimal R code in either package. I'm curious how you determined they weren't any good. –  Joshua Ulrich Feb 16 '11 at 23:02
Well, RcppDE makes the same algorithm a C++ implementation. Prasad could use the package as a template to wrap another optimizer he has access too. –  Dirk Eddelbuettel Feb 16 '11 at 23:07
@Dirk: I was merely noting the history that they wrap the C implementation from Storn's website. –  Joshua Ulrich Feb 16 '11 at 23:10
How do you know the percent of time spent in your R function is small? If you pause it 10 times at random while it's running, you'll get a good rough measure of that percent. –  Mike Dunlavey Feb 17 '11 at 2:41
@Joshua that's a good question -- when I fit the distribution using a MLE method (in the `ghyp` package), for a set of 10,000 points, it fits it in under 5 seconds, whereas when I am trying to fit it by minimizing a goodness-of-fit function, using `optim + L-BFGS-B` it takes at least 2 minutes (not sure exactly because I often just kill it). Same with RcppDE/DEOptim. In other words, my speed expectations were set by how fast the MLE worked. It's possible I'm being naive about MLE and need to understand better why it can be faster than minimizing a goodness of fit measure. –  Prasad Chalasani Feb 17 '11 at 2:43