I am writing a function to fit many glm models. To just give you some ideas about the function, I include a small section of my code. With the help of several SO users, the function works for my analysis purpose now. However, sometimes, particularly when the sample size is relatively small, it can take quite long time to finish the whole process. To reduce the time, I am considering changing some details of iterative maximization, such as maximum number of iterations. I have not found a way to do it, maybe because I am still not familiar with R terminology. Any suggestions to do this or other ways to reduce time would be appreciated.

all_glm <- function(crude, xlist, data, family = "binomial", ...) {
  # md_lst include formula for many models to be fitted  
  comb_lst <- unlist(lapply(1:n, function(x) combn(xlist, x, simplify=F)), recursive=F)
  md_lst   <- lapply(comb_lst,function(x) paste(crude, "+", paste(x, collapse = "+")))
  models  <- lapply(md_lst, function(x) glm(as.formula(x), family = family, data = data))
  OR      <- unlist(lapply(models, function(x) broom::tidy(x, exponentiate = TRUE)$estimate[2]))


EDIT Thanks to @BenBolker who directed me to the package fastglm, I end up with several r packages which could provide faster alternatives to glm. I have tried fastglm and speedglm. It appears than both are faster than glm on my machine.

# from 
n <- 25000
k <- 500
y <- rbinom(n, size = 1, prob = 0.5)
x <- round( matrix(rnorm(n*k),n,k),digits=3)
colnames(x) <-paste("s",1:k,sep = "")
df <- data.frame(y,x)
fo <- as.formula(paste("y~",paste(paste("s",1:k,sep=""),collapse="+")))   

# Fit three models: 
system.time(m_glm <- glm(fo, data=df, family = binomial))
system.time(m_speedglm <- speedglm(fo, data= df, family = binomial()))
system.time(m_fastglm <- fastglm(x, y, family = binomial()))

> system.time(m_glm <- glm(fo, data=df, family = binomial))
   user  system elapsed 
  56.51    0.22   58.73 
> system.time(m_speedglm <- speedglm(fo, data= df, family = binomial()))
   user  system elapsed 
  17.28    0.04   17.55 
> system.time(m_fastglm <- fastglm(x, y, family = binomial()))
   user  system elapsed 
  23.87    0.09   24.12 
  • 2
    have you tried the fastglm package?
    – Ben Bolker
    Oct 17, 2019 at 23:39
  • @BenBolker Thanks. No, I haven't, I will give a try to see if it makes a difference. Oct 17, 2019 at 23:46
  • 1
    @BenBolker I have tried fastglm. It allows users to assign the threshold tolerance for convergence, and maximum number of iterations, but it requires x must be a matrix object, which may not be convenient for some end users . Oct 18, 2019 at 0:33
  • 1
    are your predictors all numeric, or are some factors (categorical)? A minimal reproducible example would be great. What are the typical dimensions of your problem (number of observations, number of predictors)? Have you considered a penalized (lasso/ridge) approach?
    – Ben Bolker
    Oct 18, 2019 at 0:47
  • 2
    This is the tiniest of notes. I am unaware of a faster implementation in R, however with a bit of trickery possibly openGL or other fully c++ based implementations might be slightly faster. As for the problem with fastglm only allowing numeric x and y i suggest using the standard glm call glm(fo, data = df, family = binomial, method = "fastglm"). The call to glm will take care of converting your formula to a model matrix and give the necessary input for fastglm. Note that printing the output does take a long time, if you use this method (for unknown reasons to me).
    – Oliver
    Oct 18, 2019 at 18:00

1 Answer 1


The IRLS algorithm typically used for fitting glms requires matrix inversion/decomposition at each iteration. fastglm offers several different options for the decomposition and the default choice is a slower but more stable option (QR with column-pivoting). If your only interest is speed, then one of the two available Cholesky-type decompositions will improve the speed dramatically, which would be more advisable than just changing the number of IRLS iterations. Another notable difference between fastglm and standard IRLS implementations is its careful use of half-steps in order to prevent divergence (IRLS can diverge in practice in a number of cases).

The method argument of fastglm allows one to change the decomposition. option 2 gives the vanilla Cholesky decomposition and option 3 gives a slightly more stable version of this. On my computer, the timings for your provided example are:

> system.time(m_glm <- glm(fo, data=df, family = binomial))
   user  system elapsed 
 23.206   0.429  23.689 

> system.time(m_speedglm <- speedglm(fo, data= df, family = binomial()))
   user  system elapsed 
 15.448   0.283  15.756 

> system.time(m_fastglm <- fastglm(x, y, family = binomial(), method = 2))
   user  system elapsed 
  2.159   0.055   2.218 

> system.time(m_fastglm <- fastglm(x, y, family = binomial(), method = 3))
   user  system elapsed 
  2.247   0.065   2.337 

With regards to using broom with fastglm objects, I can look into that.

Another note about decompositions: When fastglm uses the QR decomposition, it is working with the design matrix directly. Although speedglm technically offers a QR decomposition, it works by first computing $X^TX$ and decomposing this, which is more numerically unstable than a QR on X.

  • Thanks a lot. I have learned something interesting and helpful from your answer. Nov 2, 2019 at 23:19

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