(The tl;dr is you should a) increase nodesize to >> 1 and b) exclude very low-importance feature columns, maybe even exclude (say) 80% of your columns. Your issue is almost surely not
na.roughfix, but if you suspect that, run
na.roughfix separately as a standalone step, before calling
randomForest. Get that red herring out of the way at first.)
Now, all of the following advice only applies until you blow out your memory limits, so measure your memory usage, and make sure you're not exceeding. (Start with ridiculously small parameters, then scale them up, measure the runtime, and keep checking it didn't increase disproportionately.)
The main parameters affecting the performance of randomForest are:
- mtry (less is faster)
- number of features/cols in data - more is quadratically slower, or worse! See below
- number of observations/rows in data
- ncores (more is faster - as long as parallel option is being used)
- some performance boost by setting importance=F and proximity=F (don't compute proximity matrix)
- Never ever use the insane default
nodesize=1, for classification! In Breiman's package, you can't directly set maxdepth, but use
nodesize as a proxy for that, and also read all the good advice at: CrossValidated: "Practical questions on tuning Random Forests"
- So here your data has 4.2e+5 rows, then if each node shouldn't be smaller than ~0.01%, try
nodesize=42. (First try nodesize=4200 (1%), see how fast it is, then rerun, adjusting nodesize down. Empirically determine a good nodesize for this dataset.)
- runtime is proportional to ~ 2^D_max, i.e. polynomial to (-log1p(nodesize))
- optionally you can also speedup by using sampling, see
Then a first-order estimate of runtime, denoting mtry=M, ntrees=T, ncores=C, nfeatures=F, nrows=R, maxdepth=D_max, is:
Runtime proportional to: T * F^2 * (R^1.something) * 2^D_max / C
(Again, all bets are off if you exceed memory. Also, try running on only one core, then 2, then 4 and verify you actually do get linear speedup. And not slowdown.)
(The effect of large R is worse than linear, maybe quadratic, since tree-partitioning has to consider all partitions of the data rows; certainly it's somewhat worse than linear. Check that by using sampling or indexing to only give it say 10% of rows).
Tip: keeping lots of crap low-importance features quadratically increases runtime, for a sublinear increase in accuracy. This is because at each node, we must consider all possible feature selection (or whatever number mtry) allows. And within each tree, we must consider all (F-choose-mtry) possible combinations of features.
So here's my methodology, doing "fast-and-dirty feature-selection for performance":
- generate a tree normally (slow), although use a sane
nodesize=42 or larger
- look at rf$importances or
randomForest::varImpPlot(). Pick only the top-K features, where you choose K; for a silly-fast example, choose K=3. Save that entire list for future reference.
- now rerun the tree but only give it
- confirm that speed is quadratically faster, and oob.error is not much worse
- once you know your variable importances, you can turn off
- tweak mtry and nodesize (tweak one at a time), rerun and measure speed improvement
- plot your performance results on logarithmic axes
- post us the results! Did you corroborate the above? Any comments on memory usage?
(Note that the above is not a statistically valid procedure for actual feature-selection, do not rely on it for that, read randomForest package for the actual proper methods for RF-based feature-selection.)