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r""" Building the required library in this example requires a source distribution of NumPy or clone of the NumPy git repository since distributions.c is not included in binary distributions. On *nix, execute in numpy/random/src/distributions export ${PYTHON_VERSION}=3.8 # Python version export PYTHON_INCLUDE=#path to Python's include folder, usually \ ${PYTHON_HOME}/include/python${PYTHON_VERSION}m export NUMPY_INCLUDE=#path to numpy's include folder, usually \ ${PYTHON_HOME}/lib/python${PYTHON_VERSION}/site-packages/numpy/core/include gcc -shared -o libdistributions.so -fPIC distributions.c \ -I${NUMPY_INCLUDE} -I${PYTHON_INCLUDE} mv libdistributions.so ../../_examples/numba/ On Windows rem PYTHON_HOME and PYTHON_VERSION are setup dependent, this is an example set PYTHON_HOME=c:\Anaconda set PYTHON_VERSION=38 cl.exe /LD .\distributions.c -DDLL_EXPORT \ -I%PYTHON_HOME%\lib\site-packages\numpy\core\include \ -I%PYTHON_HOME%\include %PYTHON_HOME%\libs\python%PYTHON_VERSION%.lib move distributions.dll ../../_examples/numba/ """ import os import numba as nb import numpy as np from cffi import FFI from numpy.random import PCG64 ffi = FFI() if os.path.exists('./distributions.dll'): lib = ffi.dlopen('./distributions.dll') elif os.path.exists('./libdistributions.so'): lib = ffi.dlopen('./libdistributions.so') else: raise RuntimeError('Required DLL/so file was not found.') ffi.cdef(""" double random_standard_normal(void *bitgen_state); """) x = PCG64() xffi = x.cffi bit_generator = xffi.bit_generator random_standard_normal = lib.random_standard_normal def normals(n, bit_generator): out = np.empty(n) for i in range(n): out[i] = random_standard_normal(bit_generator) return out normalsj = nb.jit(normals, nopython=True) # Numba requires a memory address for void * # Can also get address from x.ctypes.bit_generator.value bit_generator_address = int(ffi.cast('uintptr_t', bit_generator)) norm = normalsj(1000, bit_generator_address) print(norm[:12])