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Python package to convert numerical series & numpy arrays into compressed strings

pip install numcompress

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numcompress

Simple way to compress and decompress numerical series & numpy arrays.

  • Easily gets you above 80% compression ratio
  • You can specify the precision you need for floating points (up to 10 decimal points)
  • Useful to store or transmit stock prices, monitoring data & other time series data in compressed string format

Compression algorithm is based on google encoded polyline format. I modified it to preserve arbitrary precision and apply it to any numerical series. The work is motivated by usefulness of time aware polyline built by Arjun Attam at HyperTrack. After building this I came across arrays that are much efficient than lists in terms memory footprint. You might consider using that over numcompress if you don't care about conversion to string for transmitting or storing purpose.

Installation

pip install numcompress

Usage

from numcompress import compress, decompress

# Integers
>>> compress([14578, 12759, 13525])
'B_twxZnv_nB_bwm@'

>>> decompress('B_twxZnv_nB_bwm@')
[14578.0, 12759.0, 13525.0]
# Floats - lossless compression
# precision argument specifies how many decimal points to preserve, defaults to 3
>>> compress([145.7834, 127.5989, 135.2569], precision=4)
'Csi~wAhdbJgqtC'

>>> decompress('Csi~wAhdbJgqtC')
[145.7834, 127.5989, 135.2569]
# Floats - lossy compression
>>> compress([145.7834, 127.5989, 135.2569], precision=2)
'Acn[rpB{n@'

>>> decompress('Acn[rpB{n@')
[145.78, 127.6, 135.26]
# compressing and decompressing numpy arrays
>>> from numcompress import compress_ndarray, decompress_ndarray
>>> import numpy as np

>>> series = np.random.randint(1, 100, 25).reshape(5, 5)
>>> compressed_series = compress_ndarray(series)
>>> decompressed_series = decompress_ndarray(compressed_series)

>>> series
array([[29, 95, 10, 48, 20],
       [60, 98, 73, 96, 71],
       [95, 59,  8,  6, 17],
       [ 5, 12, 69, 65, 52],
       [84,  6, 83, 20, 50]])

>>> compressed_series
'5*5,Bosw@_|_Cn_eD_fiA~tu@_cmA_fiAnyo@o|k@nyo@_{m@~heAnrbB~{BonT~lVotLoinB~xFnkX_o}@~iwCokuCn`zB_ry@'

>>> decompressed_series
array([[29., 95., 10., 48., 20.],
       [60., 98., 73., 96., 71.],
       [95., 59.,  8.,  6., 17.],
       [ 5., 12., 69., 65., 52.],
       [84.,  6., 83., 20., 50.]])

>>> (series == decompressed_series).all()
True

Compression Ratio

Test# of NumbersCompression ratio
Integers10k91.14%
Floats10k81.35%

You can run the test suite with -s switch to see the compression ratio. You can even modify the tests to see what kind of compression ratio you will get for your own input.

pytest -s

Here's a quick example showing compression ratio:

>>> series = random.sample(range(1, 100000), 50000)  # generate 50k random numbers between 1 and 100k
>>> text = compress(series)  # apply compression

>>> original_size = sum(sys.getsizeof(i) for i in series)
>>> original_size
1200000

>>> compressed_size = sys.getsizeof(text)
>>> compressed_size
284092

>>> compression_ratio = ((original_size - compressed_size) * 100.0) / original_size
>>> compression_ratio
76.32566666666666

We get ~76% compression for 50k random numbers between 1 & 100k. This ratio increases for real world numerical series as the difference between consecutive numbers tends to be lower. Think of stock prices, monitoring & other time series data.

Contribute

If you see any problem, open an issue or send a pull request. You can write to me at [email protected]