Python package for *fast* TDigest calculation.
Project description
PyTDigest: Fast streaming calculation of approximate quantiles
Python package for fast TDigest calculation.
C implementation and thin Python wrapper
suitable for big data and streaming and distributed settings
developed for smooth compatibility with Pandas and numpy
Based on previous work of Ted Dunning and Andrew Werner.
Basic example
from pytdigest import TDigest
import numpy as np
import pandas as pd
rng = np.random.default_rng(12354)
n = 100_000
x = rng.normal(loc=0, scale=10, size=n)
w = rng.exponential(scale=1, size=n)
# estimation from data is simple:
td = TDigest.compute(x, w, compression=1_000)
# td now contains "compressed" distribution: centroids with their means and weights
# TDigest can be used to provide mean or approximate quantiles (i.e. inverse CDF):
td.mean
quantiles = [0., 0.01, 0.05, 0.25, 0.5, 0.75, 0.95, 0.99, 1.]
td.inverse_cdf(quantiles)
# these results are close to numpy values (note that numpy provides only unweighted quantiles)
np.average(x, weights=w) # mean should be exact
np.quantile(x, quantiles)
# TDigest can be copied
td2 = td.copy()
# and multiple TDigests can be added together to provide approximate quantiles for the overall dataset
td + td2
Performance
Ted Dunning’s original algorithm in Java takes about ~140 ns per addition on average. This package needs about ~200 ns per addition when called from Python on numpy arrays, so the performance is fairly comparable with the original implementation. All other tested TDigest implementations in Python are much slower.
import numpy as np
from pytdigest import TDigest
import time
rng = np.random.Generator(np.random.PCG64(12345))
for n in [100_000, 1_000_000, 10_000_000]:
x = rng.normal(size=n)
w = rng.exponential(size=n)
start = time.time()
td = TDigest.compute(x, w)
end = time.time()
print(f'PyTDigest, n = {n:,}: {end - start:.3g} seconds')
# PyTDigest, n = 100,000: 0.0222 seconds
# PyTDigest, n = 1,000,000: 0.21 seconds
# PyTDigest, n = 10,000,000: 2.02 seconds
Similar packages
Several Python packages or wrappers exist for the TDigest algorithm.
tdigest
The most popular on GitHub is a pure Python tdigest package. Pure Python implementation is indeed very slow – more than 100x slower than this package:
import numpy as np
from pytdigest import TDigest
from tdigest import TDigest as TDigestPython
import time
rng = np.random.Generator(np.random.PCG64(12345))
n = 100_000
x = rng.normal(size=n)
w = rng.exponential(size=n)
start = time.time()
td = TDigest.compute(x, w)
end = time.time()
print(f'PyTDigest: {end - start:.3g} seconds')
# PyTDigest: 0.0246 seconds
tdp = TDigestPython()
start = time.time()
tdp.batch_update(x)
end = time.time()
print(f'TDigest: {end - start:.3g} seconds')
# TDigest: 7.26 seconds
Different weights for can be used in tdigest only with update method for adding a single observation.
t-digest CFFI
Other package is t-digest CFFI, a thin Python wrapper over C implementation. It does not pass batch updates into the C layer, so the iteration has to be done in python:
import numpy as np
from tdigest import TDigest as TDigestCFFI
import time
rng = np.random.Generator(np.random.PCG64(12345))
n = 100_000
x = rng.normal(size=n)
tdcffi = TDigestCFFI()
start = time.time()
for xx in x:
tdcffi.insert(xx)
end = time.time()
print(f'TDigest-CFFI: {end - start:.3g} seconds')
Hence this package is still almost 20x slower than this package when used over numpy arrays. In addition, t-digest CFFI package allows only for integer weights.
qtdigest
qtdigest’s own benchmarking states that 100 000 additions take about 1.7 s, so it is again almost 100x slower than this package.
tdigestc
tdigestc by ajwerner is a simple C implementation with wrappers for different languages. The Python wrapper is very basic, it is not published on PyPI and some functionality was missing in the underlying C implementation (for instance support for batch updates based on numpy arrays), so I took this package as the starting point and added several useful features for use as a standalone Python package.
Future plans
There are several improvements that can be done in the future:
TDigest can calculate exact variance in addition to mean.
Alternating merging procedure (the centroids are always merged left to right in the C implementation, however Ted Dunning states that alternating merging improves the precision).
Scaling function for merging centroids is hard-coded at the moment. Ted Dunning mentions several possible functions that can be used in merging.
Centroids can store information about their variance - the resulting TDigest should be still composable and fast and it can work much better for discrete distributions.
Documentation
Legal stuff
Apache License, Version 2.0, http://www.apache.org/licenses/LICENSE-2.0
- Copyright (c) 2015 Ted Dunning, All rights reserved.
- Copyright (c) 2018 Andrew Werner, All rights reserved.
- Copyright (c) 2022 Tomas Protivinsky, All rights reserved.
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