I've created an SVM in R using the kernlab package, however it's running incredibly slow (20,000 predictions takes ~45 seconds on win64 R distribution). CPU is running at 25% and RAM utilization is a mere 17% ... it's not a hardware bottleneck. Similar calculations using data mining algorithms in SQL Server analysis services run about 40x faster.
Through trial and error, we discovered that the laplacedot kernel gives us the best results by a wide margin. Rbfdot is about 15% less accurate, but twice as fast (but still too slow). The best performance is vanilladot. It runs more or less instantly but the accuracy is way too low to use.
We'd ideally like to use the laplacedot kernel but to do so we need a massive speedup. Does anyone have any ideas on how to do this?
Here is some profiling information I generated using rprof. It looks like most of the time is spent in low level math calls (the rest of the profile consists of similar data as rows 16-40). This should run very quickly but it looks like the code is just not optimized (and I don't know where to start).
Edit: Sample code to reproduce:
dummy.length = 20000; source.data = as.matrix(cbind(sample(1:dummy.length)/1300, sample(1:dummy.length)/1900)) colnames(source.data) <- c("column1", "column2") y.value = as.matrix((sample(1:dummy.length) + 9) / 923) model <- ksvm(source.data[,], y.value, type="eps-svr", kernel="laplacedot",C=1, kpar=list(sigma=3));
The source data has 7 numeric columns (floating point) and 20,000 rows. This takes about 2-3 minutes to train. The next call generates the predictions and consistently takes 40 seconds to run:
predictions <- predict(model, source.data)
Edit 2: The Laplacedot kernel calculates the dot product of two vectors using the following formula. This corresponds rather closely with the profr output. Strangely, it appears that the negative symbol (just before the round function) consumes about 50% of the runtime.
return(exp(-sigma * sqrt(-(round(2 * crossprod(x, y) - crossprod(x,x) - crossprod(y,y), 9)))))
Edit 3: Added sample code to reproduce - this gives me about the same runtimes as my actual data.