I have a large data set (~30m observations, ~800 variables) and I need to residualize 700 variables by regressing each of them on 3 variables and then storing the residuals. Here is what I am currently doing:

io_d[, (vars_to_residualize_list) := lapply(.SD, 
        function(X) {lm(X ~ X1 + X2 + X3)$residuals}),
        .SDcols = vars_to_residualize]

Where vars_to_residualize is a list of the variables to residualize and vars_to_residualize_list is a list of the new names for the residuals.

This takes about 70 hours to get through all the variables.

Is there a faster way to do this?

  • Are X1, X2 and X3 all continuous? Dense? You should definitely parallelize across the 700 variables. You can also skip down a level and use lm.fit directly instead of creating the whole lm object. Read the source code of lm a bit to get an idea on this. – MichaelChirico Oct 11 at 16:36
  • 1
    They are all factors. Parallelizing is a good idea. I will look into lm.fit. – gannawag Oct 11 at 16:38
  • 3
    if X1, X2, and X3 are all factors, you're not really regressing on 3 variables, you're regressing on n1 -1 + n2 - 1 + n3 - 1 variables where nk is the number of levels of Xk. The upside is that this regression is likely massively sparse and you can use sparse.model.matrix & sparse regression methods will likely be a lot faster. If you're careful about your matrix algebra/regression techniques you may not even need to compute the design matrix at all. – MichaelChirico Oct 11 at 16:40
  • 1
    One last thing -- if X1:X3 are always the same across your 700 regressions, you should use model.matrix or sparse.model.matrix _only once` to create and store your design matrix. No need to bother creating this object 700 different times if it's a repeat. – MichaelChirico Oct 11 at 16:48

Maybe this will help you reduce times, significantly fastLm() is much slower than lm(); slightly modify the code of fLmSEXP to be able to extract the residuals.

## start from SEXP, most conversions, longest code
src <- '
Rcpp::List fLmSEXP(SEXP Xs, SEXP ys) {
Rcpp::NumericMatrix Xr(Xs);
Rcpp::NumericVector yr(ys);
int n = Xr.nrow(), k = Xr.ncol();
arma::mat X(Xr.begin(), n, k, false);
arma::colvec y(yr.begin(), yr.size(), false);
// fit model y ~ X, extract residuals
arma::colvec coef = arma::solve(X, y);
arma::colvec res  = y - X*coef;
// return the results
return Rcpp::List::create(Rcpp::Named("coefficients")=coef,Rcpp::Named("res")=res);
cppFunction(code=src, depends="RcppArmadillo")

I create my data frame

df <- data.frame(replicate(3,sample(1:4,300000,rep=TRUE)))
df = cbind(X = rnorm(300000),df)
           X X1 X2 X3
1  0.6269854  1  4  3
2  0.4641201  1  1  4
3 -0.5625020  3  1  4
4  0.0452215  2  1  2
5  2.2453335  3  3  2
6  0.4045328  1  3  3
m <- as.matrix(cbind(X = df[,1],cbind(I = 1,df[,2:4])))

I compare the results of both functions

lm_res = lm(X ~ X1 + X2 + X3, data = df)$residuals,
flm_res = fLmSEXP(m[,2:5],m[,1])$res, replications = 100)[,1:4]

    test replications elapsed relative
2 flm_res          100    4.14    1.00
1  lm_res          100   12.46    3.01

I hope this will be helpful, or at least give you a way.

  • Looks interesting - I will give it a try! – gannawag Oct 16 at 18:35

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