Skip to main content

A package for estimating heterogeneous probability density functions.

Project description

pysparkplug

pysparkplug

python license tests

Composable density estimation for heterogeneous records. A single observation can be a tuple of a category, a real, a count sequence, a vector, a set, or a tree — and pysparkplug fits a probabilistic model to a dataset of them by expectation–maximization, locally on vectorized NumPy/Numba or distributed across Spark, Dask, Ray, MPI, or Torch (GPU).

The unit of composition is the distribution: leaves (Gaussian, categorical, Poisson, …) combine into tuples, tuples become mixture components, mixtures become HMM emissions, to any depth. A model and the estimator that fits it have the same shape — so what you can express, you can fit.

Contents

Installation · Quickstart · Core concepts · Distribution catalog · Probabilistic programming · Frequentist & Bayesian · Engines & orchestration · Enumeration & ranking · Beyond fitting · Examples · Tests · License

Installation

Python 3.10+ (developed on 3.12). On PyPI as pysp-learn; the import name is pysp.

pip install pysp-learn          # base (numpy, scipy, mpmath): every distribution + local EM
pip install "pysp-learn[all]"   # acceleration, scale-out, and connectors

The base install fits every distribution locally. Acceleration and scale-out are opt-in extras:

Extra Adds
numba JIT-compiled hot paths (falls back to pure NumPy when absent)
torch GPU / autograd engine
spark · dask · mpi distributed estimation backends
pandas · arrow · sql · mongo · hadoop · data data-source connectors
gmpy2 GMP-FFT big-integer multiply for count-DP ranking
umap model-based UMAP embeddings
sympy · sage symbolic / closed-form export
grammar graph-grammar models (networkx)

Development: git clone … && pip install -e ".[all]".

Quickstart

Each record here is a (category, real, variable-length count sequence). Fit a two-component mixture straight from a list of records:

from pysp.stats import *
from pysp.inference import optimize

data = [
    ('a', -0.4, [5, 7]),       ('b', 4.9, [11, 9]),
    ('a',  0.2, [6, 5, 4]),    ('b', 5.3, [10, 12, 11]),
    ('a', -1.1, [4, 6]),       ('b', 4.5, [9, 10]),
    ('a',  0.7, [5, 5]),       ('b', 5.1, [12, 8]),
    ('a', -0.2, [7, 6, 5]),    ('b', 4.7, [9, 11]),
]

# The estimator mirrors the distribution's structure exactly.
est = MixtureEstimator([CompositeEstimator((
    CategoricalEstimator(),
    GaussianEstimator(),
    SequenceEstimator(PoissonEstimator(), len_estimator=CategoricalEstimator()),
))] * 2)

model = optimize(data, est, max_its=100)
model.sampler(seed=0).sample(3)   # draw new records from the fitted model

The same model in the shorter pysp.ppl dialect is a few lines.

Core concepts

Each family is five cooperating pieces:

Piece Role
...Distribution parameters + log_density(x) and vectorized seq_log_density(encoded)
...Sampler draw observations — dist.sampler(seed).sample(size)
...Estimator declares the model to fit; closed-form M-step in estimate()
...Accumulator sufficient statistics for the E-step, mergeable across data partitions
...DataEncoder packs raw Python records into arrays for the fast path

optimize(data, est) (in pysp.inference) runs EM to convergence — vectorized locally, or distributed via backend=. Related entry points:

  • best_of — multi-restart EM
  • StreamingEstimator — online EM
  • fit_mle / fit_map — autograd fitting with typed priors
  • pysp.utils.automatic.get_estimator(data) — infer an estimator from raw data

Families live in pysp.stats; operations on them are grouped by concern:

  • pysp.inference — fit: MLE / EM / MAP / conjugate / NUTS / VI / Fisher
  • pysp.enumeration — rank / top-k / unranking
  • pysp.ops — quantize / condition / marginalize / project
  • pysp.describe(x) — report what any object supports

Drawing is a method, not a concern: dist.sampler(seed).sample(n).

Distribution catalog

About 90 families in pysp.stats. The distinguishing feature: the combinators model a whole heterogeneous record as one distribution. One observation under each:

Model One observation
GaussianDistribution / PoissonDistribution / CategoricalDistribution -0.31 / 7 / 'b'
MultivariateGaussianDistribution [1.2, -0.4, 0.8]
CompositeDistribution((Cat, Gaussian, Poisson)) ('a', -0.31, 7)
RecordDistribution({...}) {'country': 'US', 'age': 41, 'spend': 12.5}
SequenceDistribution(Poisson) [5, 4, 6] (variable length)
OptionalDistribution(Gaussian) -0.31 or None
MixtureDistribution([...]) / HiddenMarkovModelDistribution a component's shape, with the cluster / state latent
  • Univariate: Gaussian, Student-t/Cauchy, Logistic, LogGaussian, Laplace, Uniform, Exponential, Gamma, Inverse Gamma/Gaussian, Half-Normal, Gumbel, Beta, Weibull, Rayleigh, Pareto, Poisson, Bernoulli, Geometric, Binomial, Negative Binomial, Log-Series, von Mises, Dirichlet, categorical; multivariate/diagonal Gaussian, von Mises–Fisher, multivariate Student-t.
  • Combinators: Composite (tuples), Record (named fields), Sequence, Optional (missing data), Transform, Conditional, Weighted.
  • Latent structure: mixtures (plain, heterogeneous, hierarchical, joint, semi-supervised), LDA, PLSI, probabilistic PCA, HMMs (standard, segmental, lookback, tree, quantized), PCFGs, Markov chains, hidden associations, IBP, Pitman-Yor processes, Bernoulli sets.
  • Permutations & graphs: Mallows / Plackett-Luce, matchings, spanning trees, random graphs (Erdős–Rényi, stochastic block, random dot-product), Spearman ranking, and graph grammars over networks (vertex-replacement / NLC and hyperedge-replacement) — log_density is the marginal likelihood, computed by parsing the graph back to the start symbol.
  • Bayesian: conjugate priors (NormalGamma, NormalWishart, MvnGamma, Dirichlet, SymmetricDirichlet) and variational Dirichlet-process / hierarchical-DP mixtures.

Estimator knobs (every family): pseudo_count (regularization) · prior= (conjugate; None is MLE) · keys (tie statistics across parts). One stem per family (<Stem>Distribution / Estimator / …); legacy spellings remain as aliases.

Probabilistic programming (pysp.ppl)

A concise dialect over the same distributions. One rule: any parameter slot is a value, the token free (estimate it), or another distribution (a prior).

from pysp.ppl import Normal, Mix, Markov, Field, free

Normal(0.0, 1.0)              # fixed parameters
Normal(free, free)            # estimate the mean and standard deviation
Normal(Normal(0, 10), 1.0)    # a prior on the mean (hierarchical)

data = [-2.1, 1.9, -1.8, 2.3, -2.0, 2.1]                          # reals from two clusters
m = Mix([Normal(free, free), Normal(free, free)]).fit(data)
m.posterior(data)                                                 # per-point responsibilities

seqs = [[0.1, 5.1, 4.9], [4.8, 5.0], [0.0, 0.2]]                  # variable-length real sequences
Markov(Normal(free, free), states=2).fit(seqs)                    # 2-state Gaussian HMM

#   y[i] ~ Normal(b0 + b1*x[i] + b2*z[i], sd)   — a linear model
Normal(free * Field("x") + free * Field("z") + free, free).fit(y, given={"x": x, "z": z})

a, b = Normal(0, 10, name="a"), Normal(0, 10, name="b")
Mix([Normal(a, 1), Normal(b, 1)]).fit(data, constraints=a < b)    # ordered means break label-switching
  • how= selects the route: auto takes an exact path when one exists, else conjugate | em | map | vi | vmp | mcmc | hmc | nuts | ensemble.
  • Constraints among named variables are plain comparisons (combine with & | ~) and shape both inference and sampling.
  • Closed form: for conjugate / exponential-family / mixture models, .fit(...) returns the exact posterior.
  • Constructors: Mix · Seq · Markov · LDA · MVN · DiagGaussian · LocalLevel · AR1 · Graph; compare([m1, m2], data) ranks fitted models.

The dialect is thin — the pysp.stats classes underneath are untouched.

Frequentist & Bayesian

The prior is the only switch — no prior is MLE; a conjugate prior= makes the same machinery Bayesian:

from pysp.inference.priors import NormalGammaPrior

GaussianEstimator()                          # MLE
GaussianEstimator(prior=NormalGammaPrior())  # closed-form conjugate posterior — same optimize() call
  • optimize / fit pick the objective from the model — likelihood, MAP, or variational ELBO.
  • BayesianStreamingEstimator carries a posterior across batches; pysp.stats.bayes adds (hierarchical) Dirichlet-process mixtures.
  • Gradient MAP with typed priors: pysp.inference.gradient_fit.fit_map (NormalGammaPrior / DirichletPrior / MixturePrior).
  • Honest densities: supports(x, ExactDensity) / describe(x) flag when a model's log_density is a variational bound (e.g. LDA's per-document ELBO) rather than the exact log p(x).

Engines & orchestration

Distributions own the likelihood and sufficient-statistic math; compute engines supply the array ops, device, and precision — so scale-out is a backend argument, not a rewrite:

from pysp.engines import TorchEngine

optimize(data, est, engine=TorchEngine(device="cuda", dtype="float32"))   # GPU
optimize(data, est, precision="auto")                                     # stats still accumulate in float64
optimize(rdd,  est, backend="spark")                                      # also: mp · dask · mpi · ray · lightning
  • The same EM contract runs unchanged on NumPy, Numba, Torch, or a symbolic backend.
  • New frameworks register a factory (register_encoded_data_backend) — no dispatch to edit.
  • The planner (pysp.utils.parallel.planner) turns a hardware budget into a memory-aware placement (chunking, device assignment, Torch sharding) you compute once and reuse.
  • The SymbolicEngine runs a density through SymPy, so a model can emit its closed-form log-density as LaTeX / SymPy / Sage.

Enumeration & ranking

Discrete and structured models enumerate their support in descending-probability order and answer exact rank / cumulative-probability queries — even when the support is enormous or unbounded:

e = dist.enumerator()
e.top_k(5)        # the 5 most probable (value, log_prob)
e.top_p(0.95)     # smallest set covering 95% of the mass (the nucleus)
e.rank(value)     # how many values are strictly more probable than `value`
e.seek(10_000)    # the ~10,000th most probable value, by structural count-DP
  • Decomposable families (Composite / Record / Sequence / MarkovChain): rank ↔ value is an exact count-DP at any depth (count_dp_rank, count_dp_seek); budget-bounded quantized indexes (count_budget_index) seek the most-probable region of an infinite support (the gmpy2 extra uses GMP's FFT multiply for the big-integer convolution).
  • Non-decomposable families (mixtures, HMMs): exact marginal rank is provably hard, so they return the Viterbi bound or a certified Monte-Carlo estimate (density_rank, with a standard error) — never a silent approximation.
  • Continuous families realize the same operations through cdf(x) / quantile(q).

Beyond fitting

  • Inference (pysp.inference): mcmc (MH / HMC / NUTS / VMP), em (hard, annealed, ECM, Monte-Carlo, variational, online, restart), fisher (geometry views), and the Posterior algebra — posterior(model, data, over="latent"|"params"|"predictive") returns one object you sample / mean / interval. An engine-agnostic facade runs NUTS/ADVI on any differentiable target with parallel chains (R̂ + pooled ESS).
  • Design & analysis of experiments (pysp.doe): space-filling designs, GP Bayesian optimization, and the analysis half — Sobol/Morris sensitivity, uncertainty propagation, Kennedy-O'Hagan calibration.
  • Embeddings (pysp.utils.hvis): model-based t-SNE / UMAP over per-record posteriors.
  • Supervised & non-iid models (pysp.models): GP regression, neural regressors, random forests (a conditional p(y | x) leaf), random graphs, grammars, knowledge graphs.
  • MLOps (pysp.inference): reproducible model artifacts (fit_with_provenance → a ModelHeader with config, data hash, convergence, timing, resources, env), drift detection + ModelMonitor (retrain-and-swap), and a versioned ModelRegistry + ModelService (scoring + activity logging). A container / Kubernetes serving layer lives in the separate pysparkplug-deploy package.

Examples

Self-contained scripts in examples/ — each samples from a known model, refits, and recovers it (no downloads):

cd examples
python gallery_univariate_example.py    # tour the scalar families (also gallery_{multivariate,combinators,…})
python gallery_structured_example.py    # mixtures / HMMs / LDA / latent-variable models
python ppl_example.py                   # the equation-style pysp.ppl surface
python production_example.py            # provenance, registry, serving, drift, checkpoints
python scaling_example.py               # the same fit distributed by backend= (local / mp / mpi / spark)

Distributed backends (see scaling_example.py): local and mp run out of the box; mpi and Spark need a launcher. Spark also needs a JVM (Java 17/21) with workers on the driver's Python:

export JAVA_HOME=$(/usr/libexec/java_home -v 17)
export PYSPARK_PYTHON=/path/to/venv/bin/python PYSPARK_DRIVER_PYTHON=$PYSPARK_PYTHON

Tests

python -m pytest                                       # fast gate (parallel), ~25 s
python -m pytest -m "not optional and not benchmark"   # full suite incl. slow tests

base_dist_test.py exercises each family end to end: sampler repeatability, str/eval round-trips, vectorized-vs-scalar density agreement, EM convergence. See pysp/tests/README.md.

License

MIT — see LICENSE. Originally developed at Lawrence Livermore National Laboratory (LLNL-CODE-844837).

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

pysp_learn-0.5.2.tar.gz (2.1 MB view details)

Uploaded Source

Built Distribution

If you're not sure about the file name format, learn more about wheel file names.

pysp_learn-0.5.2-py3-none-any.whl (2.6 MB view details)

Uploaded Python 3

File details

Details for the file pysp_learn-0.5.2.tar.gz.

File metadata

  • Download URL: pysp_learn-0.5.2.tar.gz
  • Upload date:
  • Size: 2.1 MB
  • Tags: Source
  • Uploaded using Trusted Publishing? Yes
  • Uploaded via: twine/6.1.0 CPython/3.13.12

File hashes

Hashes for pysp_learn-0.5.2.tar.gz
Algorithm Hash digest
SHA256 50874333caf3e244983b2c0443ed8a7e0a88cdbd793c6dc1d54787652a969664
MD5 72a8a33fb0ee6b2eee84dd76514ab78b
BLAKE2b-256 e8a7a9dae32b07fa82db3fc7525376de47d268845f47f5c32d6e46ced17cbfce

See more details on using hashes here.

Provenance

The following attestation bundles were made for pysp_learn-0.5.2.tar.gz:

Publisher: publish.yml on gmboquet/pysparkplug

Attestations: Values shown here reflect the state when the release was signed and may no longer be current.

File details

Details for the file pysp_learn-0.5.2-py3-none-any.whl.

File metadata

  • Download URL: pysp_learn-0.5.2-py3-none-any.whl
  • Upload date:
  • Size: 2.6 MB
  • Tags: Python 3
  • Uploaded using Trusted Publishing? Yes
  • Uploaded via: twine/6.1.0 CPython/3.13.12

File hashes

Hashes for pysp_learn-0.5.2-py3-none-any.whl
Algorithm Hash digest
SHA256 e654fedcd95f34545dd53084ed0ed57ea3f88b36d5a80522b69887c3b550cc08
MD5 8a46e3ad364b84470e5c8dd405c58378
BLAKE2b-256 6331ada792c971af0c4d3436fed452e6f0f67a8699ad1e86323ced2eb4ff128e

See more details on using hashes here.

Provenance

The following attestation bundles were made for pysp_learn-0.5.2-py3-none-any.whl:

Publisher: publish.yml on gmboquet/pysparkplug

Attestations: Values shown here reflect the state when the release was signed and may no longer be current.

Supported by

AWS Cloud computing and Security Sponsor Datadog Monitoring Depot Continuous Integration Fastly CDN Google Download Analytics Pingdom Monitoring Sentry Error logging StatusPage Status page