CmdStanR (Command Stan R) is a lightweight interface to Stan for R users that provides an alternative to the traditional RStan interface. See the Comparison with RStan section later in this vignette for more details on how the two interfaces differ.
Using CmdStanR requires installing the cmdstanr R package and also CmdStan, the command line interface to Stan. First we install the R package by running the following command in R.
# we recommend running this is a fresh R session or restarting your current session
install.packages("cmdstanr", repos = c('https://stan-dev.r-universe.dev', getOption("repos")))
We can now load the package like any other R package. We’ll also load the bayesplot and posterior packages to use later in examples.
CmdStanR requires a working installation of CmdStan, the shell interface to Stan. If you don’t have CmdStan installed then CmdStanR can install it for you, assuming you have a suitable C++ toolchain. The requirements are described in the CmdStan Guide:
To double check that your toolchain is set up properly you can call
the check_cmdstan_toolchain()
function:
If your toolchain is configured correctly then CmdStan can be
installed by calling the install_cmdstan()
function:
Before CmdStanR can be used it needs to know where the CmdStan installation is located. When the package is loaded it tries to help automate this to avoid having to manually set the path every session:
If the environment variable "CMDSTAN"
exists at load
time then its value will be automatically set as the default path to
CmdStan for the R session. This is useful if your CmdStan installation
is not located in the default directory that would have been used by
install_cmdstan()
(see #2).
If no environment variable is found when loaded but any directory
in the form ".cmdstan/cmdstan-[version]"
, for example
".cmdstan/cmdstan-2.23.0"
, exists in the user’s home
directory (Sys.getenv("HOME")
, not the current
working directory) then the path to the CmdStan with the largest version
number will be set as the path to CmdStan for the R session. This is the
same as the default directory that install_cmdstan()
uses
to install the latest version of CmdStan, so if that’s how you installed
CmdStan you shouldn’t need to manually set the path to CmdStan when
loading CmdStanR.
If neither of these applies (or you want to subsequently change the
path) you can use the set_cmdstan_path()
function:
To check the path to the CmdStan installation and the CmdStan version
number you can use cmdstan_path()
and
cmdstan_version()
:
The cmdstan_model()
function creates a new CmdStanModel
object from a file containing a Stan program. Under the hood, CmdStan is
called to translate a Stan program to C++ and create a compiled
executable. Here we’ll use the example Stan program that comes with the
CmdStan installation:
file <- file.path(cmdstan_path(), "examples", "bernoulli", "bernoulli.stan")
mod <- cmdstan_model(file)
The object mod
is an R6 reference object of class CmdStanModel
and behaves similarly to R’s reference class objects and those in object
oriented programming languages. Methods are accessed using the
$
operator. This design choice allows for CmdStanR and CmdStanPy to provide a
similar user experience and share many implementation details.
The Stan program can be printed using the $print()
method:
The path to the compiled executable is returned by the
$exe_file()
method:
The $sample()
method for CmdStanModel
objects runs Stan’s default MCMC algorithm. The data
argument accepts a named list of R objects (like for RStan) or a path to
a data file compatible with CmdStan (JSON or R dump).
# names correspond to the data block in the Stan program
data_list <- list(N = 10, y = c(0,1,0,0,0,0,0,0,0,1))
fit <- mod$sample(
data = data_list,
seed = 123,
chains = 4,
parallel_chains = 4,
refresh = 500 # print update every 500 iters
)
There are many more arguments that can be passed to the
$sample()
method. For details follow this link to its
separate documentation page:
The $sample()
method creates R6 CmdStanMCMC
objects,
which have many associated methods. Below we will demonstrate some of
the most important methods. For a full list, follow this link to the
CmdStanMCMC
documentation:
The $summary()
method calls summarise_draws()
from the
posterior package. The first argument specifies the
variables to summarize and any arguments after that are passed on to
posterior::summarise_draws()
to specify which summaries to
compute, whether to use multiple cores, etc.
fit$summary()
fit$summary(variables = c("theta", "lp__"), "mean", "sd")
# use a formula to summarize arbitrary functions, e.g. Pr(theta <= 0.5)
fit$summary("theta", pr_lt_half = ~ mean(. <= 0.5))
# summarise all variables with default and additional summary measures
fit$summary(
variables = NULL,
posterior::default_summary_measures(),
extra_quantiles = ~posterior::quantile2(., probs = c(.0275, .975))
)
CmdStan itself provides a stansummary
utility that can
be called using the $cmdstan_summary()
method. This method
will print summaries but won’t return anything.
The $draws()
method can be used to extract the posterior draws in formats provided by
the posterior
package. Here we demonstrate only the draws_array
and
draws_df
formats, but the posterior
package supports other useful formats as well.
# default is a 3-D draws_array object from the posterior package
# iterations x chains x variables
draws_arr <- fit$draws() # or format="array"
str(draws_arr)
# draws x variables data frame
draws_df <- fit$draws(format = "df")
str(draws_df)
print(draws_df)
To convert an existing draws object to a different format use the
posterior::as_draws_*()
functions.
# this should be identical to draws_df created via draws(format = "df")
draws_df_2 <- as_draws_df(draws_arr)
identical(draws_df, draws_df_2)
In general, converting to a different draws format in this way will
be slower than just setting the appropriate format initially in the call
to the $draws()
method, but in most cases the speed
difference will be minor.
The vignette Working with
Posteriors has more details on posterior draws, including how to
reproduce the structured output RStan users are accustomed to getting
from rstan::extract()
.
Plotting posterior distributions is as easy as passing the object
returned by the $draws()
method directly to plotting
functions in our bayesplot
package.
The $sampler_diagnostics()
method extracts the values of the sampler parameters
(treedepth__
, divergent__
, etc.) in formats
supported by the posterior package. The default is as a
3-D array (iteration x chain x variable).
The $diagnostic_summary()
method will display any
sampler diagnostic warnings and return a summary of diagnostics for each
chain.
We see the number of divergences for each of the four chains, the number of times the maximum treedepth was hit for each chain, and the E-BFMI for each chain.
In this case there were no warnings, so in order to demonstrate the warning messages we’ll use one of the CmdStanR example models that suffers from divergences.
After fitting there is a warning about divergences. We can also
regenerate this warning message later using
fit$diagnostic_summary()
.
CmdStan itself provides a diagnose
utility that can be
called using the $cmdstan_diagnose()
method. This method
will print warnings but won’t return anything.
CmdStanR also supports running Stan’s optimization algorithms and its
algorithms for variational approximation of full Bayesian inference.
These are run via the $optimize()
, $laplace()
,
$variational()
, and $pathfinder()
methods,
which are called in a similar way to the $sample()
method
demonstrated above.
We can find the (penalized) maximum likelihood estimate (MLE) using
$optimize()
.
fit_mle <- mod$optimize(data = data_list, seed = 123)
fit_mle$print() # includes lp__ (log prob calculated by Stan program)
fit_mle$mle("theta")
Here’s a plot comparing the penalized MLE to the posterior
distribution of theta
.
For optimization, by default the mode is calculated without the
Jacobian adjustment for constrained variables, which shifts the mode due
to the change of variables. To include the Jacobian adjustment and
obtain a maximum a posteriori (MAP) estimate set
jacobian=TRUE
. See the Maximum
Likelihood Estimation section of the CmdStan User’s Guide for more
details.
The $laplace()
method produces a sample from a normal approximation centered at the
mode of a distribution in the unconstrained space. If the mode is a MAP
estimate, the samples provide an estimate of the mean and standard
deviation of the posterior distribution. If the mode is the MLE, the
sample provides an estimate of the standard error of the likelihood.
Whether the mode is the MAP or MLE depends on the value of the
jacobian
argument when running optimization. See the Laplace
Sampling chapter of the CmdStan User’s Guide for more details.
Here we pass in the fit_map
object from above as the
mode
argument. If mode
is omitted then
optimization will be run internally before taking draws from the normal
approximation.
We can run Stan’s experimental Automatic Differentiation Variational
Inference (ADVI) using the $variational()
method. For details on the ADVI algorithm see the CmdStan
User’s Guide.
Stan version 2.33 introduced a new variational method called
Pathfinder, which is intended to be faster and more stable than ADVI.
For details on how Pathfinder works see the section in the CmdStan
User’s Guide. Pathfinder is run using the $pathfinder()
method.
Let’s extract the draws, make the same plot we made after running the other algorithms, and compare them all. approximation, and compare them all. In this simple example the distributions are quite similar, but this will not always be the case for more challenging problems.
mcmc_hist(fit_pf$draws("theta"), binwidth = 0.025) +
ggplot2::labs(subtitle = "Approximate posterior from pathfinder") +
ggplot2::xlim(0, 1)
mcmc_hist(fit_vb$draws("theta"), binwidth = 0.025) +
ggplot2::labs(subtitle = "Approximate posterior from variational") +
ggplot2::xlim(0, 1)
mcmc_hist(fit_laplace$draws("theta"), binwidth = 0.025) +
ggplot2::labs(subtitle = "Approximate posterior from Laplace") +
ggplot2::xlim(0, 1)
mcmc_hist(fit$draws("theta"), binwidth = 0.025) +
ggplot2::labs(subtitle = "Posterior from MCMC") +
ggplot2::xlim(0, 1)
For more details on the $optimize()
,
$laplace()
, $variational()
, and
pathfinder()
methods, follow these links to their
documentation pages.
The $save_object()
method provided by CmdStanR is the most convenient way to save a fitted
model object to disk and ensure that all of the contents are available
when reading the object back into R.
But if your model object is large, then $save_object()
could take a long time. $save_object()
reads the CmdStan results files into memory, stores them in the model
object, and saves the object with saveRDS()
. To speed up
the process, you can emulate $save_object()
and replace saveRDS
with the much faster
qsave()
function from the qs
package.
# Load CmdStan output files into the fitted model object.
fit$draws() # Load posterior draws into the object.
try(fit$sampler_diagnostics(), silent = TRUE) # Load sampler diagnostics.
try(fit$init(), silent = TRUE) # Load user-defined initial values.
try(fit$profiles(), silent = TRUE) # Load profiling samples.
# Save the object to a file.
qs::qsave(x = fit, file = "fit.qs")
# Read the object.
fit2 <- qs::qread("fit.qs")
Storage is even faster if you discard results you do not need to save. The following example saves only posterior draws and discards sampler diagnostics, user-specified initial values, and profiling data.
# Load posterior draws into the fitted model object and omit other output.
fit$draws()
# Save the object to a file.
qs::qsave(x = fit, file = "fit.qs")
# Read the object.
fit2 <- qs::qread("fit.qs")
See the vignette How does CmdStanR work? for more information about the composition of CmdStanR objects.
There are additional vignettes available that discuss other aspects of using CmdStanR. These can be found online at the CmdStanR website:
To ask a question please post on the Stan forums:
To report a bug, suggest a feature (including additions to these vignettes), or to start contributing to CmdStanR development (new contributors welcome!) please open an issue on GitHub: