Title: | Parallel GLM |
---|---|
Description: | Provides a parallel estimation method for generalized linear models without compiling with a multithreaded LAPACK or BLAS. |
Authors: | Benjamin Christoffersen [cre, aut] , Anthony Williams [cph], Boost developers [cph] |
Maintainer: | Benjamin Christoffersen <[email protected]> |
License: | GPL-2 |
Version: | 0.1.7 |
Built: | 2024-11-07 06:42:19 UTC |
Source: | CRAN |
Function like glm
which can make the computation
in parallel. The function supports most families listed in family
.
See "vignette("parglm", "parglm")
" for run time examples.
parglm(formula, family = gaussian, data, weights, subset, na.action, start = NULL, offset, control = list(...), contrasts = NULL, model = TRUE, x = FALSE, y = TRUE, ...) parglm.fit(x, y, weights = rep(1, NROW(x)), start = NULL, etastart = NULL, mustart = NULL, offset = rep(0, NROW(x)), family = gaussian(), control = list(), intercept = TRUE, ...)
parglm(formula, family = gaussian, data, weights, subset, na.action, start = NULL, offset, control = list(...), contrasts = NULL, model = TRUE, x = FALSE, y = TRUE, ...) parglm.fit(x, y, weights = rep(1, NROW(x)), start = NULL, etastart = NULL, mustart = NULL, offset = rep(0, NROW(x)), family = gaussian(), control = list(), intercept = TRUE, ...)
formula |
an object of class |
family |
a |
data |
an optional data frame, list or environment containing the variables in the model. |
weights |
an optional vector of 'prior weights' to be used in the fitting process. Should
be |
subset |
an optional vector specifying a subset of observations to be used in the fitting process. |
na.action |
a function which indicates what should happen when the data contain |
start |
starting values for the parameters in the linear predictor. |
offset |
this can be used to specify an a priori known component to be included in the linear predictor during fitting. |
control |
a list of parameters for controlling the fitting process.
For parglm.fit this is passed to |
contrasts |
an optional list. See the |
model |
a logical value indicating whether model frame should be included as a component of the returned value. |
x , y
|
For For |
... |
For For |
etastart |
starting values for the linear predictor. Not supported. |
mustart |
starting values for the vector of means. Not supported. |
intercept |
logical. Should an intercept be included in the null model? |
The current implementation uses min(as.integer(n / p), nthreads)
threads where n
is the number observations, p
is the
number of covariates, and nthreads
is the nthreads
element of
the list
returned by parglm.control
. Thus, there is likely little (if
any) reduction in computation time if p
is almost equal to n
.
The current implementation cannot handle p > n
.
glm
object as returned by glm
but differs mainly by the qr
element. The qr
element in the object returned by parglm
(.fit
) only has the
matrix from the QR decomposition.
# small example from `help('glm')`. Fitting this model in parallel does # not matter as the data set is small clotting <- data.frame( u = c(5,10,15,20,30,40,60,80,100), lot1 = c(118,58,42,35,27,25,21,19,18), lot2 = c(69,35,26,21,18,16,13,12,12)) f1 <- glm (lot1 ~ log(u), data = clotting, family = Gamma) f2 <- parglm(lot1 ~ log(u), data = clotting, family = Gamma, control = parglm.control(nthreads = 2L)) all.equal(coef(f1), coef(f2))
# small example from `help('glm')`. Fitting this model in parallel does # not matter as the data set is small clotting <- data.frame( u = c(5,10,15,20,30,40,60,80,100), lot1 = c(118,58,42,35,27,25,21,19,18), lot2 = c(69,35,26,21,18,16,13,12,12)) f1 <- glm (lot1 ~ log(u), data = clotting, family = Gamma) f2 <- parglm(lot1 ~ log(u), data = clotting, family = Gamma, control = parglm.control(nthreads = 2L)) all.equal(coef(f1), coef(f2))
Auxiliary function for parglm
fitting.
parglm.control(epsilon = 1e-08, maxit = 25, trace = FALSE, nthreads = 1L, block_size = NULL, method = "LINPACK")
parglm.control(epsilon = 1e-08, maxit = 25, trace = FALSE, nthreads = 1L, block_size = NULL, method = "LINPACK")
epsilon |
positive convergence tolerance. |
maxit |
integer giving the maximal number of IWLS iterations. |
trace |
logical indicating if output should be produced doing estimation. |
nthreads |
number of cores to use. You may get the best performance by
using your number of physical cores if your data set is sufficiently large.
Using the number of physical CPUs/cores may yield the best performance
(check your number e.g., by calling |
block_size |
number of observation to include in each parallel block. |
method |
string specifying which method to use. Either |
The LINPACK
method uses the same QR method as glm.fit
for the final QR decomposition.
This is the dqrdc2
method described in qr
. All other QR
decompositions but the last are made with DGEQP3
from LAPACK
.
See Wood, Goude, and Shaw (2015) for details on the QR method.
The FAST
method computes the Fisher information and then solves the normal
equation. This is faster but less numerically stable.
A list with components named as the arguments.
Wood, S.N., Goude, Y. & Shaw S. (2015) Generalized additive models for large datasets. Journal of the Royal Statistical Society, Series C 64(1): 139-155.
# use one core clotting <- data.frame( u = c(5,10,15,20,30,40,60,80,100), lot1 = c(118,58,42,35,27,25,21,19,18), lot2 = c(69,35,26,21,18,16,13,12,12)) f1 <- parglm(lot1 ~ log(u), data = clotting, family = Gamma, control = parglm.control(nthreads = 1L)) # use two cores f2 <- parglm(lot1 ~ log(u), data = clotting, family = Gamma, control = parglm.control(nthreads = 2L)) all.equal(coef(f1), coef(f2))
# use one core clotting <- data.frame( u = c(5,10,15,20,30,40,60,80,100), lot1 = c(118,58,42,35,27,25,21,19,18), lot2 = c(69,35,26,21,18,16,13,12,12)) f1 <- parglm(lot1 ~ log(u), data = clotting, family = Gamma, control = parglm.control(nthreads = 1L)) # use two cores f2 <- parglm(lot1 ~ log(u), data = clotting, family = Gamma, control = parglm.control(nthreads = 2L)) all.equal(coef(f1), coef(f2))