| Type: | Package |
| Title: | Fast and Stable Fitting of Generalized Linear Models using 'RcppEigen' |
| Version: | 0.0.3 |
| Maintainer: | Jared Huling <jaredhuling@gmail.com> |
| Description: | Fits generalized linear models efficiently using 'RcppEigen'. The iteratively reweighted least squares implementation utilizes the step-halving approach of Marschner (2011) <doi:10.32614/RJ-2011-012> to help safeguard against convergence issues. |
| BugReports: | https://github.com/jaredhuling/fastglm/issues |
| License: | GPL-2 | GPL-3 [expanded from: GPL (≥ 2)] |
| Encoding: | UTF-8 |
| Imports: | Rcpp (≥ 0.12.13), methods |
| Depends: | bigmemory |
| LinkingTo: | Rcpp, RcppEigen, BH, bigmemory |
| RoxygenNote: | 7.1.1 |
| Suggests: | knitr, rmarkdown, glm2 |
| VignetteBuilder: | knitr |
| NeedsCompilation: | yes |
| Packaged: | 2022-05-23 15:40:18 UTC; huling |
| Author: | Jared Huling [aut, cre], Douglas Bates [cph], Dirk Eddelbuettel [cph], Romain Francois [cph], Yixuan Qiu [cph] |
| Repository: | CRAN |
| Date/Publication: | 2022-05-23 16:50:02 UTC |
big.matrix prod
Description
big.matrix prod
big.matrix prod
Usage
## S4 method for signature 'big.matrix,vector'
x %*% y
## S4 method for signature 'vector,big.matrix'
x %*% y
Arguments
x |
big.matrix |
y |
numeric vector |
deviance method for fastglm fitted objects
Description
deviance method for fastglm fitted objects
Usage
## S3 method for class 'fastglm'
deviance(object, ...)
Arguments
object |
fastglm fitted object |
... |
not used |
Value
The value of the deviance extracted from the object
family method for fastglm fitted objects
Description
family method for fastglm fitted objects
Usage
## S3 method for class 'fastglm'
family(object, ...)
Arguments
object |
fastglm fitted object |
... |
not used |
Value
returns the family of the fitted object
fast generalized linear model fitting
Description
fast generalized linear model fitting
bigLm default
Usage
fastglm(x, ...)
## Default S3 method:
fastglm(
x,
y,
family = gaussian(),
weights = NULL,
offset = NULL,
start = NULL,
etastart = NULL,
mustart = NULL,
method = 0L,
tol = 1e-08,
maxit = 100L,
...
)
Arguments
x |
input model matrix. Must be a matrix object |
... |
not used |
y |
numeric response vector of length nobs. |
family |
a description of the error distribution and link function to be used in the model.
For |
weights |
an optional vector of 'prior weights' to be used in the fitting process. Should be a numeric vector. |
offset |
this can be used to specify an a priori known component to be included in the linear predictor during fitting. This should be a numeric vector of length equal to the number of cases |
start |
starting values for the parameters in the linear predictor. |
etastart |
starting values for the linear predictor. |
mustart |
values for the vector of means. |
method |
an integer scalar with value 0 for the column-pivoted QR decomposition, 1 for the unpivoted QR decomposition, 2 for the LLT Cholesky, or 3 for the LDLT Cholesky |
tol |
threshold tolerance for convergence. Should be a positive real number |
maxit |
maximum number of IRLS iterations. Should be an integer |
Value
A list with the elements
coefficients |
a vector of coefficients |
se |
a vector of the standard errors of the coefficient estimates |
rank |
a scalar denoting the computed rank of the model matrix |
df.residual |
a scalar denoting the degrees of freedom in the model |
residuals |
the vector of residuals |
s |
a numeric scalar - the root mean square for residuals |
fitted.values |
the vector of fitted values |
Examples
x <- matrix(rnorm(10000 * 100), ncol = 100)
y <- 1 * (0.25 * x[,1] - 0.25 * x[,3] > rnorm(10000))
system.time(gl1 <- glm.fit(x, y, family = binomial()))
system.time(gf1 <- fastglm(x, y, family = binomial()))
system.time(gf2 <- fastglm(x, y, family = binomial(), method = 1))
system.time(gf3 <- fastglm(x, y, family = binomial(), method = 2))
system.time(gf4 <- fastglm(x, y, family = binomial(), method = 3))
max(abs(coef(gl1) - gf1$coef))
max(abs(coef(gl1) - gf2$coef))
max(abs(coef(gl1) - gf3$coef))
max(abs(coef(gl1) - gf4$coef))
## Not run:
nrows <- 50000
ncols <- 50
bkFile <- "bigmat2.bk"
descFile <- "bigmatk2.desc"
bigmat <- filebacked.big.matrix(nrow=nrows, ncol=ncols, type="double",
backingfile=bkFile, backingpath=".",
descriptorfile=descFile,
dimnames=c(NULL,NULL))
for (i in 1:ncols) bigmat[,i] = rnorm(nrows)*i
y <- 1*(rnorm(nrows) + bigmat[,1] > 0)
system.time(gfb1 <- fastglm(bigmat, y, family = binomial(), method = 3))
## End(Not run)
fast generalized linear model fitting
Description
fast generalized linear model fitting
Usage
fastglmPure(
x,
y,
family = gaussian(),
weights = rep(1, NROW(y)),
offset = rep(0, NROW(y)),
start = NULL,
etastart = NULL,
mustart = NULL,
method = 0L,
tol = 1e-07,
maxit = 100L
)
Arguments
x |
input model matrix. Must be a matrix object |
y |
numeric response vector of length nobs. |
family |
a description of the error distribution and link function to be used in the model.
For |
weights |
an optional vector of 'prior weights' to be used in the fitting process. Should be a numeric vector. |
offset |
this can be used to specify an a priori known component to be included in the linear predictor during fitting. This should be a numeric vector of length equal to the number of cases |
start |
starting values for the parameters in the linear predictor. |
etastart |
starting values for the linear predictor. |
mustart |
values for the vector of means. |
method |
an integer scalar with value 0 for the column-pivoted QR decomposition, 1 for the unpivoted QR decomposition, 2 for the LLT Cholesky, 3 for the LDLT Cholesky, 4 for the full pivoted QR decomposition, 5 for the Bidiagonal Divide and Conquer SVD |
tol |
threshold tolerance for convergence. Should be a positive real number |
maxit |
maximum number of IRLS iterations. Should be an integer |
Value
A list with the elements
coefficients |
a vector of coefficients |
se |
a vector of the standard errors of the coefficient estimates |
rank |
a scalar denoting the computed rank of the model matrix |
df.residual |
a scalar denoting the degrees of freedom in the model |
residuals |
the vector of residuals |
s |
a numeric scalar - the root mean square for residuals |
fitted.values |
the vector of fitted values |
Examples
set.seed(1)
x <- matrix(rnorm(1000 * 25), ncol = 25)
eta <- 0.1 + 0.25 * x[,1] - 0.25 * x[,3] + 0.75 * x[,5] -0.35 * x[,6] #0.25 * x[,1] - 0.25 * x[,3]
y <- 1 * (eta > rnorm(1000))
yp <- rpois(1000, eta ^ 2)
yg <- rgamma(1000, exp(eta) * 1.75, 1.75)
# binomial
system.time(gl1 <- glm.fit(x, y, family = binomial()))
system.time(gf1 <- fastglmPure(x, y, family = binomial(), tol = 1e-8))
system.time(gf2 <- fastglmPure(x, y, family = binomial(), method = 1, tol = 1e-8))
system.time(gf3 <- fastglmPure(x, y, family = binomial(), method = 2, tol = 1e-8))
system.time(gf4 <- fastglmPure(x, y, family = binomial(), method = 3, tol = 1e-8))
max(abs(coef(gl1) - gf1$coef))
max(abs(coef(gl1) - gf2$coef))
max(abs(coef(gl1) - gf3$coef))
max(abs(coef(gl1) - gf4$coef))
# poisson
system.time(gl1 <- glm.fit(x, yp, family = poisson(link = "log")))
system.time(gf1 <- fastglmPure(x, yp, family = poisson(link = "log"), tol = 1e-8))
system.time(gf2 <- fastglmPure(x, yp, family = poisson(link = "log"), method = 1, tol = 1e-8))
system.time(gf3 <- fastglmPure(x, yp, family = poisson(link = "log"), method = 2, tol = 1e-8))
system.time(gf4 <- fastglmPure(x, yp, family = poisson(link = "log"), method = 3, tol = 1e-8))
max(abs(coef(gl1) - gf1$coef))
max(abs(coef(gl1) - gf2$coef))
max(abs(coef(gl1) - gf3$coef))
max(abs(coef(gl1) - gf4$coef))
# gamma
system.time(gl1 <- glm.fit(x, yg, family = Gamma(link = "log")))
system.time(gf1 <- fastglmPure(x, yg, family = Gamma(link = "log"), tol = 1e-8))
system.time(gf2 <- fastglmPure(x, yg, family = Gamma(link = "log"), method = 1, tol = 1e-8))
system.time(gf3 <- fastglmPure(x, yg, family = Gamma(link = "log"), method = 2, tol = 1e-8))
system.time(gf4 <- fastglmPure(x, yg, family = Gamma(link = "log"), method = 3, tol = 1e-8))
max(abs(coef(gl1) - gf1$coef))
max(abs(coef(gl1) - gf2$coef))
max(abs(coef(gl1) - gf3$coef))
max(abs(coef(gl1) - gf4$coef))
logLik method for fastglm fitted objects
Description
logLik method for fastglm fitted objects
Usage
## S3 method for class 'fastglm'
logLik(object, ...)
Arguments
object |
fastglm fitted object |
... |
not used |
Value
Returns an object of class logLik
Obtains predictions and optionally estimates standard errors of those predictions from a fitted generalized linear model object.
Description
Obtains predictions and optionally estimates standard errors of those predictions from a fitted generalized linear model object.
Usage
## S3 method for class 'fastglm'
predict(
object,
newdata = NULL,
type = c("link", "response"),
se.fit = FALSE,
dispersion = NULL,
...
)
Arguments
object |
a fitted object of class inheriting from " |
newdata |
a matrix to be used for prediction |
type |
the type of prediction required. The default is on the scale of the linear predictors;
the alternative " The value of this argument can be abbreviated. |
se.fit |
logical switch indicating if standard errors are required. |
dispersion |
the dispersion of the GLM fit to be assumed in computing the standard errors.
If omitted, that returned by |
... |
further arguments passed to or from other methods. |
print method for fastglm objects
Description
print method for fastglm objects
Usage
## S3 method for class 'fastglm'
print(x, ...)
Arguments
x |
object to print |
... |
not used |
residuals method for fastglm fitted objects
Description
residuals method for fastglm fitted objects
Usage
## S3 method for class 'fastglm'
residuals(
object,
type = c("deviance", "pearson", "working", "response", "partial"),
...
)
Arguments
object |
fastglm fitted object |
type |
type of residual to be returned |
... |
not used |
Value
a vector of residuals
summary method for fastglm fitted objects
Description
summary method for fastglm fitted objects
Usage
## S3 method for class 'fastglm'
summary(object, dispersion = NULL, ...)
Arguments
object |
fastglm fitted object |
dispersion |
the dispersion parameter for the family used.
Either a single numerical value or |
... |
not used |
Value
a summary.fastglm object
Examples
x <- matrix(rnorm(10000 * 10), ncol = 10)
y <- 1 * (0.25 * x[,1] - 0.25 * x[,3] > rnorm(10000))
fit <- fastglm(x, y, family = binomial())
summary(fit)