I write respective Python wrapper functions for abstracting interaction with shared object, which is compiled using make genlib. Check wrapper definition in module ff_p.
Before you use Python module defined in this directory, make sure you've run
make genliband generated shared object.
Now you can import ff_p and perform basic prime field arithmetics.
Note, prime field modulus is
2**64 - 2**32 + 1
from ff_p import *
assert 3 == ff_p_add(1, 2)
assert 18446744069414584320 == ff_p_sub(1, 2)
assert 19456 == ff_p_multiply(19, 1 << 10)
assert (1 << 10) == ff_p_exponentiate(2, 10)
assert 18302628881372282881 == ff_p_inverse(128)
assert 8198552919739815254 == ff_p_divide(2, 9)There're some randomised testcases I've written, for strongly asserting results produced by ff_p module are indeed correct, using another Finite Field implementation galois module.
For running those test cases, I suggest you start with enabling virtualenv
# assuming you're in this directory
python3 -m pip install --user virtualenv # if `venv` not installed
python3 -m venv .
source bin/activate
# you're inside `venv` nowNow you can install required dependencies inside venv
python3 -m pip install -r requirements.txtFinally run randomized test cases
python3 ff_p_test.pyWhen done, consider deactivating virtual environment
deactivate