Speed comparison

Speed comparison

Neuroblastoma data

Consider the neuroblastoma data. There are 3418 labeled examples. If we consider subsets, how long does it take to compute the AUM and its directional derivatives?

data(neuroblastomaProcessed, package="penaltyLearning")
library(data.table)
nb.err <- data.table(neuroblastomaProcessed$errors)
nb.err[, example := paste0(profile.id, ".", chromosome)]
nb.X <- neuroblastomaProcessed$feature.mat
(N.pred.vec <- as.integer(10^seq(1, log10(nrow(nb.X)), by=0.5)))
#> [1]   10   31  100  316 1000 3162
if(requireNamespace("atime")){
  aum.pL.list <- atime::atime(
    N=N.pred.vec,
    setup={
      N.pred.names <- rownames(nb.X)[1:N]
      N.diffs.dt <- aum::aum_diffs_penalty(nb.err, N.pred.names)
      pred.dt <- data.table(example=N.pred.names, pred.log.lambda=0)
    },
    penaltyLearning={
      roc.list <- penaltyLearning::ROChange(nb.err, pred.dt, "example")
    },
    aum={
      aum.list <- aum::aum(N.diffs.dt, pred.dt$pred.log.lambda)
    })
  plot(aum.pL.list)
}
#> Le chargement a nécessité le package : atime
#> Warning in atime::atime(N = N.pred.vec, setup = {: please increase max N or
#> seconds.limit, because only one N was evaluated for expr.name: penaltyLearning
#> Le chargement a nécessité le package : directlabels

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From the plot above we can see that both packages have similar asymptotic time complexity. However aum is faster by orders of magnitude.

R implementation

In this section we show a base R implementation of aum.

diffs.df <- data.frame(
  example=c(0,1,1,2,3),
  pred=c(0,0,1,0,0),
  fp_diff=c(1,1,1,0,0),
  fn_diff=c(0,0,0,-1,-1))
pred.log.lambda <- c(0,1,-1,0)
microbenchmark::microbenchmark("C++"={
  aum::aum(diffs.df, pred.log.lambda)
}, R={
  thresh.vec <- with(diffs.df, pred-pred.log.lambda[example+1])
  s.vec <- order(thresh.vec)
  sort.diffs <- data.frame(diffs.df, thresh.vec)[s.vec,]
  for(fp.or.fn in c("fp","fn")){
    ord.fun <- if(fp.or.fn=="fp")identity else rev
    fwd.or.rev <- sort.diffs[ord.fun(1:nrow(sort.diffs)),]
    fp.or.fn.diff <- fwd.or.rev[[paste0(fp.or.fn,"_diff")]]
    last.in.run <- c(diff(fwd.or.rev$thresh.vec) != 0, TRUE)
    after.or.before <-
      ifelse(fp.or.fn=="fp",1,-1)*cumsum(fp.or.fn.diff)[last.in.run]
    distribute <- function(values)with(fwd.or.rev, structure(
      values,
      names=thresh.vec[last.in.run]
    )[paste(thresh.vec)])
    out.df <- data.frame(
      before=distribute(c(0, after.or.before[-length(after.or.before)])),
      after=distribute(after.or.before))
    sort.diffs[
      paste0(fp.or.fn,"_",ord.fun(c("before","after")))
    ] <- as.list(out.df[ord.fun(1:nrow(out.df)),])
  }
  AUM.vec <- with(sort.diffs, diff(thresh.vec)*pmin(fp_before,fn_before)[-1])
  list(
    aum=sum(AUM.vec),
    deriv_mat=sapply(c("after","before"),function(b.or.a){
      s <- if(b.or.a=="before")1 else -1
      f <- function(p.or.n,suffix=b.or.a){
        sort.diffs[[paste0("f",p.or.n,"_",suffix)]]
      }
      fp <- f("p")
      fn <- f("n")
      aggregate(
        s*(pmin(fp+s*f("p","diff"),fn+s*f("n","diff"))-pmin(fp, fn)),
        list(sort.diffs$example),
        sum)$x
    }))
}, times=10)
#> Unit: microseconds
#>  expr      min       lq      mean   median       uq      max neval
#>   C++   706.12   738.72   776.132   763.14   795.40   878.40    10
#>     R 50971.56 52175.48 56842.228 53770.06 55076.96 78110.76    10

It is clear that the C++ implementation is several orders of magnitude faster.

Synthetic data

library(data.table)
max.N <- 1e6
(N.pred.vec <- as.integer(10^seq(1, log10(max.N), by=0.5)))
#>  [1]      10      31     100     316    1000    3162   10000   31622  100000
#> [10]  316227 1000000
max.y.vec <- rep(c(0,1), l=max.N)
max.diffs.dt <- aum::aum_diffs_binary(max.y.vec)
set.seed(1)
max.pred.vec <- rnorm(max.N)
if(requireNamespace("atime")){
  aum.sort.list <- atime::atime(
    N=N.pred.vec,
    setup={
      N.diffs.dt <- max.diffs.dt[1:N]
      N.pred.vec <- max.pred.vec[1:N]
    },
    dt_sort={
      N.diffs.dt[order(N.pred.vec)]
    },
    R_sort_radix={
      sort(N.pred.vec, method="radix")
    },
    R_sort_quick={
      sort(N.pred.vec, method="quick")
    },
    aum_sort={
      aum.list <- aum:::aum_sort_interface(N.diffs.dt, N.pred.vec)
    })
  plot(aum.sort.list)
}
#> Warning in ggplot2::scale_y_log10("median line, min/max band"): log-10 transformation introduced infinite values.
#> log-10 transformation introduced infinite values.
#> log-10 transformation introduced infinite values.

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