CmdStanRb
Ruby interface to Stan, a library a for performing high performance statistical computations, i.e. full Bayesian Inference.
Installation
gem install cmd_stan_rb
Installation for IRuby notebooks
gem install cmd_stan_rb
… and then re-register your Ruby kernel by
iruby register --force
Before you can start…
This project makes use of CmdStan to compile models with the Stan compiler and incorporating additional tooling from the Stan ecosystem. There are battle-tested similar projects for other Programming languages are i.e.
Because of its dependency to CmdStan
, you need to get CmdStan
on board to
make CmdStanRb
work. In the future I'd like to happen this automatically, but
for now you need to do this manually.
The easiest way is cloning the repository to a location of your choice. I'd
recommend moving it inside the directory of cmd_stan_rb
under a subfolder
named vendor
:
cd cmd_stan_rb && mkdir vendor && cd vendor && git clone https://github.com/stan-dev/cmdstan
Then, remember the path to that directory, as we need CmdStanRb to point to that directory by setting a config variable
Sometimes you have to cd
into your cmdstan
directory and run
git submodule update --init --recursive
Usage
To see some examples with detailed context, you may want to consult one of the example jupyter notebooks. I.e, here's how one performs linear regression with CmdStandRb. If you like monkeys and pirates, check the example of an A/B test by fitting models based on exponential distribution.
# Tell CmdStanRb where your CmdStan repository is located.
# If you skip this step, the default value is "vendor/cmdstan"
CmdStanRb.configuration.cmdstan_dir = "~/path/to/cmdstan"
# Optional: Tell CmdStanRb where to store the models
CmdStanRb.configuration.model_dir = "/Users/robin/cmd_stan_rb-models"
# Prepare Stan compiler and assistent tooling
CmdStanRb.build_binaries
# Now we're ready to fit some models 👨🔬
# First, define your model. The first argument is a name,
# which is used to identify your model for re-use later.
model =
Stan::Model.new("bernoulli-test") do
# Stan code goes here as a string
%q{
data {
int<lower=0> N;
int<lower=0,upper=1> y[N];
}
parameters {
real<lower=0,upper=1> theta;
}
model {
theta ~ beta(1,1); // uniform prior on interval 0,1
y ~ bernoulli(theta);
}
}
end
# Translate model
model.compile
# Specify data you've observed
model.data = {
"N" => 4,
"y" => [0,1,0,0]
}
# Run simulation to obtain samples from posterior distribution
result = model.fit(warmup: 500, samples: 2000) # Arguments are optional
# Print result
puts model.show
The latter command shows the simulation result:
Inference for Stan model: b439_model
1 chains: each with iter=(1000); warmup=(0); thin=(1); 1000 iterations saved.
Warmup took (0.0062) seconds, 0.0062 seconds total
Sampling took (0.013) seconds, 0.013 seconds total
Mean MCSE StdDev 5% 50% 95% N_Eff N_Eff/s R_hat
lp__ -4.4 3.5e-02 0.77 -5.9 -4.1 -3.8 4.9e+02 3.7e+04 1.0e+00
accept_stat__ 0.90 4.4e-03 0.15 0.53 0.97 1.0 1.2e+03 9.2e+04 1.0e+00
stepsize__ 1.1 nan 0.00 1.1 1.1 1.1 nan nan nan
treedepth__ 1.4 1.5e-02 0.48 1.0 1.0 2.0 1.0e+03 7.6e+04 1.0e+00
n_leapfrog__ 2.3 3.2e-02 0.97 1.0 3.0 3.0 9.2e+02 6.8e+04 1.0e+00
divergent__ 0.00 nan 0.00 0.00 0.00 0.00 nan nan nan
energy__ 4.9 5.2e-02 1.1 3.9 4.6 6.8 4.3e+02 3.2e+04 1.0e+00
theta 0.34 9.3e-03 0.18 0.071 0.32 0.64 3.7e+02 2.7e+04 1.0e+00
Samples were drawn using hmc with nuts.
For each parameter, N_Eff is a crude measure of effective sample size,
and R_hat is the potential scale reduction factor on split chains (at
convergence, R_hat=1).
Diving deeper into the model output
The return value of model.fit
, called posterior
below, holds all (sampled) posterior distributions
for each parameter, like theta
. For each parameter there is a method generated with the same name. The
method returns a Ruby Hash reflecting the sampled posterior distribution of that parameter.
Loading previously compiled models
CmdStanRb stores models in a diretory you can define by
CmdStanRb.configuration.model_dir = "/Users/robin/cmd_stan_rb-models"
If you skip this, CmdStanRb will create a folder in your home directory named cmd_stan_rb-models
and store
the model files and the compiled model binaries there.
Having compiled a model with name my-model-01
, you can load it again by
model = Stan::Model.load("my-model-01")
Note that once loaded, the model's data has been wiped out, so model.data
is blank and
needs to get set again to fit again.