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optimized computation by caching the results
ccb4a27318f1 ccb4a27318f1 eba1ea340d1f ccb4a27318f1 ccb4a27318f1 ccb4a27318f1 eba1ea340d1f eba1ea340d1f eba1ea340d1f 329ff9ed7905 329ff9ed7905 329ff9ed7905 32a0e0fcabd0 329ff9ed7905 329ff9ed7905 329ff9ed7905 329ff9ed7905 329ff9ed7905 329ff9ed7905 329ff9ed7905 329ff9ed7905 329ff9ed7905 329ff9ed7905 a47ae3e113cc 32a0e0fcabd0 329ff9ed7905 329ff9ed7905 329ff9ed7905 a47ae3e113cc 32a0e0fcabd0 329ff9ed7905 329ff9ed7905 329ff9ed7905 a47ae3e113cc 32a0e0fcabd0 329ff9ed7905 329ff9ed7905 329ff9ed7905 a47ae3e113cc 32a0e0fcabd0 329ff9ed7905 329ff9ed7905 329ff9ed7905 eba1ea340d1f | # Shamira #
Implements [Shamir's secret sharing algorithm](https://en.wikipedia.org/wiki/Shamir's_Secret_Sharing). Splits a string or a byte sequence byte-per-byte into _n_<255 shares, with any _k_ of them sufficient for reconstruction of the original input.
Outputs the shares as hexadecimal, Base32 or Base64 encoded strings.
## Installation and usage ##
Can be run straight from the cloned repository by executing the package with `python -m shamira` or simply installed with `python setup.py build`, `python setup.py install`. Then imported in your code with `import shamira` or run from the command line with `shamira`.
## Performance ##
As it is, the code is not very fast. Let's assume we have a secret of length _m_. For each byte, the splitting takes _n_ evaluations of a polynomial of order _k_ over Galois field 256, leading to _O(n\*k\*m)_ finite field multiplications. Reconstruction of the constant parameters during joining takes _O(k\*k + k\*m)_ multiplications.
Benchmark results, all values mean _seconds per byte_ of the secret length:
<table>
<tr>
<th>k / n parameters</th>
<th>Split</th>
<th>Join</th>
</tr>
<tr>
<td>2 / 3 (a Raspberry Pi 3)</td>
<td>6.08e-05</td>
<td>0.000435</td>
</tr>
<tr>
<td>2 / 3 (a laptop)</td>
<td>8.7e-06</td>
<td>7.17e-05</td>
</tr>
<tr>
<td>254 / 254 (a Raspberry Pi 3)</td>
<td>0.226</td>
<td>0.0314</td>
</tr>
<tr>
<td>254 / 254 (a laptop)</td>
<td>0.0209</td>
<td>0.00347</td>
</tr>
</table>
While the speeds are not awful, for longer secrets I recommend encrypting them with a random key of your choice and splitting only the key. Anyway, you can run your own benchmark with `shamira benchmark`
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