Compressing floating point data

Are there any lossless compression methods that can be applied to floating point time-series data, and will significantly outperform, say, writing the data as binary into a file and running it through gzip?

Reduction of precision might be acceptable, but it must happen in a controlled way (i.e. I must be able to set a bound on how many digits must be kept)

I am working with some large data files which are series of correlated `double`s, describing a function of time (i.e. the values are correlated). I don't generally need the full `double` precision but I might need more than `float`.

Since there are specialized lossless methods for images/audio, I was wondering if anything specialized exists for this situation.

Clarification: I am looking for existing practical tools rather than a paper describing how to implement something like this. Something comparable to gzip in speed would be excellent.

• What are you going to do with the data? Are you transferring it? Storing for awhile before use? Just trying to use less memory? Or are you specifically looking for a compact way to store time-series data?
– zdav
Commented Dec 25, 2011 at 17:28
• You say, "lossless", but you also say "reduction of precision is acceptable." But, reduction of precision is loss. Commented Feb 10, 2014 at 23:34
• Reducing precision in a controlled way is "lossy compression." "Lossless" means that compressing and then uncompressing yields exactly the same data, bit-for-bit, as the original. If the result is only an approximation (usually degraded in some controlled/bounded way), then that's "lossy compression." Commented Feb 13, 2014 at 18:52
• Can you leave aside the hair splitting @jameslarge ? It adds nothing to the discussion. This type of "I have to be right" compulsive arguing doesn't make StackOverflow a better place. Let's focus on solving the problem, shall we? Commented Feb 13, 2014 at 18:56
• I see you asked a similar question over on scicomp and got some excellent answers, so I wanted to make sure there's a reference to that here: scicomp.stackexchange.com/questions/1671/… Commented Jul 3, 2014 at 2:44

Here are some ideas if you want to create your own simple algorithm:

• Use xor of the current value with the previous value to obtain a set of bits describing the difference.
• Divide this difference into two parts: one part is the "mantissa bits" and one part is the "exponent bits".
• Use variable length encoding (different number of bits/bytes per value), or any compression method you choose, to save these differences. You might use separate streams for mantissas and exponents, since mantissas have more bits to compress.
• This may not work well if you are alternating between two different time-value streams sources. So you may have to compress each source into a separate stream or block.
• To lose precision, you can drop the least significant bits or bytes from the mantissa, while leaving the exponent intact.

You might want to have a look at these resources:

You might also want to try Logluv-compressed TIFF for this, thought I haven't used them myself.

One technique that the HDF5 people use is "shuffling", where you group each byte for N floating point values together. This is more likely to give you repetitive sequences of bytes which will compress better with gzip, for example.

A second method I have found which greatly reduces the size of compressed gzipped data is to first convert the data to the float16 (half-precision) format and back again to float32. This produces a lot of zeros in the output stream which can shrink file sizes by around 40-60 per cent after compression. One subtlety is that the maximum float16 value is rather low, so you may want to scale your data first, e.g. in python

``````import numpy as np
import math

input = np.array(...)

# format can only hold 65504 maximum, so we scale input data
log2max = int(math.log(np.nanmax(input), 2))
scale = 2**(log2max - 14)
scaled = input * (1./scale)

# do the conversion to float16
temp_float16 = np.array(scaled, dtype=np.float16)
# convert back again and rescale
output = np.array(temp_float16, dtype=np.float32) * scale
``````

Some tests suggest that the mean absolute fractional difference between input and output for some data are around 0.00019 with a maximum of 0.00048. This is in line with the 2**11 precision of the mantissa.

Since you state that you need a precision somewhere between 'float' and 'double': you can zero out any number of least significant bits in single- and double-precision floats. IEEE-754 floating point numers are represented binary roughly like `seeefffffffff`, which represents the value

sign*1.fffffff*2^(eee).

You can zero out the least significant fraction (f) bits. For single-precision (32-bit) floats, there are 23 fraction bits of which you can zero out up to 22. For double-precision (64-bit), it's 52 and up to 51. (If you zero out all bits, then the special values NaN and +/-inf will be lost).

Especially if the data represents decimal values such as 1.2345, this will help in data compression. That is because 1.2345 cannot be represented exactly as a binary floating point value, but rather as `0x3ff3c083126e978d`, which is not friendly to data compression. Chopping off the least significant 24 bits will result in `0x3ff3c08312000000`, which is still accurate to about 9 decimal digits (in this example, the difference is 1.6e-9).

If you do this on the raw data, and then store the differences between subsequential numbers, it will be even more compression-friendly (via gzip) if the raw data varies slowly.

Here is an example in C:

``````#include <inttypes.h>

double double_trunc(double x, int zerobits)
{
// mask is e.g. 0xffffffffffff0000 for zerobits==16
uint64_t mask = -(1LL << zerobits);
uint64_t floatbits = (*((uint64_t*)(&x)));
x = * ((double*) (&floatbits));
return x;
}
``````

And one in python/numpy:

``````import numpy as np

def float_trunc(a, zerobits):
"""Set the least significant <zerobits> bits to zero in a numpy float32 or float64 array.
Do this in-place. Also return the updated array.
Maximum values of 'nzero': 51 for float64; 22 for float32.
"""

at = a.dtype
assert at == np.float64 or at == np.float32 or at == np.complex128 or at == np.complex64
if at == np.float64 or at == np.complex128:
assert nzero <= 51
mask = 0xffffffffffffffff - (1 << nzero) + 1
bits = a.view(np.uint64)
elif at == np.float32 or at == np.complex64:
assert nzero <= 22
mask = 0xffffffff - (1 << nzero) + 1
bits = a.view(np.uint32)

return a
``````

Since you're asking for existing tools, maybe zfp will do the trick.

• Another existing tool (library), recently developed: github.com/cwida/ALP Commented Jun 18 at 9:10

Possible methods that can be used for floating-point compression:

You can test all these methods, with your data, using the icapp tool for linux and windows.

You can use Holt's Exponential smoothing algorithm (which is prediction based compression algorithm). Initially assign some weight to the data and predict the next value.If both the data are same,it produces many zero's in the MSB by doing XOR operation

TL;DR
Try ALP: https://github.com/cwida/ALP (C++). Open-source algorithm for lossless floating-point compression currently used by default in DuckDB to compress `float`/`double`. Insanely fast with the highest compression ratios overall.

In recent years, a flurry of new lossless encodings tailored for floating-point data have appeared which have not been mentioned in this thread and have already been demonstrated to be miles better than FPC, zfp, fpzip (mentioned in another answers) and any prediction-based approach or other approaches.

XOR-based approaches: Compress by doing a bitwise XOR with a previous value in the sequence (no predictors). The two best of this kind are currently:

XOR-based approaches have a few shortcomings. For instance, they cannot compress high-precision data. Also, despite being faster than predictive schemes, their per-value [de]compression cases (branchy code) and data dependencies (cannot be SIMDized) stops them from being really fast.

ALP: https://github.com/cwida/ALP (C++). Compress by losslessly transforming doubles into an integer representation (visually you could see it as moving the comma until there are no more decimals) and then encodes these integers using Frame-of-reference. This only works up to a certain precision. If floats are of high-precision (e.g. ML parameters), scheme changes to compress front-bits with dictionary encoding. ALP is insanely fast to decode (by orders of magnitude; being even faster than reading uncompressed data) while achieving higher compression ratios than all the other algorithms.

Other alternative: Zstd (https://github.com/facebook/zstd) works pretty well on floating point data. However, compression and decompression are (relatively) slow. Also, decompression must be done in relatively big blocks of values (which is bad if you only want to read few values of your data).

Disclaimer: I am one of the creators of ALP. We did a study comparing a lot of modern floating-point encodings in terms of compression ratios and encoding/decoding speed on a variety of datasets. Results can be seen here: https://dl.acm.org/doi/pdf/10.1145/3626717. Page 16:Table 4 for compression ratios comparison and Page 2:Figure 1 & Page 17:Table 5 for [de]compression speed comparison.

• Thanks for taking the time to write an update so many years later! Commented Jun 19 at 1:07

I just found this link that focuses on compressing FLOAT32: https://computing.llnl.gov/projects/floating-point-compression

My old answer below remains general to any data point

TAR ZSTD seems to be the fastest and the "compressiest" zipping algorithm out there. you can use it with a single command of:

``````tar --use-compress-program=zstd -cvf NameOFCompressedFile.tar.zst ./Files2BeCompressed
``````

For unzipping the files, use the command:

``````tar --use-compress-program=zstd -xvf NameOFCompressedFile.tar.zst
``````

And to list the contents of the file without decompressing use the command:

``````tar --use-compress-program=zstd --list --verbose --file=NameOFCompressedFile.tar.zst
``````

The zstd algorithm only works on UNIX operating systems as far as I know. you can find more info about it here: https://github.com/centminmod/tar-zstd/blob/master/readme.md