I found this useful tutorial on using low-level BLAS functions (implemented in Cython) to get big speed improvements over standard numpy linear algebra routines in python. Now, I've successfully gotten the vector product working fine. First I save the following as
import cython import numpy as np cimport numpy as np from libc.math cimport exp from libc.string cimport memset from scipy.linalg.blas import fblas REAL = np.float64 ctypedef np.float64_t REAL_t cdef extern from "/home/jlorince/flda/voidptr.h": void* PyCObject_AsVoidPtr(object obj) ctypedef double (*ddot_ptr) (const int *N, const double *X, const int *incX, const double *Y, const int *incY) nogil cdef ddot_ptr ddot=<ddot_ptr>PyCObject_AsVoidPtr(fblas.ddot._cpointer) # vector-vector multiplication cdef int ONE = 1 def vec_vec(syn0, syn1, size): cdef int lSize = size f = <REAL_t>ddot(&lSize, <REAL_t *>(np.PyArray_DATA(syn0)), &ONE, <REAL_t *>(np.PyArray_DATA(syn1)), &ONE) return f
(source code for voidptr.h available here)
Once I compile it, it works fine, and is definitely faster than
In : import linalg In : import numpy as np In : x = np.random.random(100) In : %timeit np.inner(x,x) 1000000 loops, best of 3: 1.61 µs per loop In : %timeit linalg.vec_vec(x,x,100) 1000000 loops, best of 3: 483 ns per loop In : np.all(np.inner(x,x)==linalg.vec_vec(x,x,100)) Out: True
Now, this is great, but only works for the case of calculating the dot/inner product (equivalent in this case) of two vectors. What I need to do now, implement similar functions (that I hope will offer similar speedups) for doing vector-matrix inner products. That is, I want to replicate the functionality of
np.inner when passed a 1D array and a 2D matrix:
In : x = np.random.random(5) In : y = np.random.random((5,5)) In : np.inner(x,y) Out: array([ 1.42116225, 1.13242989, 1.95690196, 1.87691992, 0.93967486])
This is equivalent to calculating the inner/dot products (again, equivalent for 1D arrays) of the 1D array and each row of the matrix:
In : [np.inner(x,row) for row in y] Out: [1.4211622497461549, 1.1324298918119025, 1.9569019618096966,1.8769199192990056, 0.93967485730285505]
From what I've seen of the BLAS documentation, I think I need to start with something like this (using dgemv):
ctypedef double (*dgemv_ptr) (const str *TRANS, const int *M, const int *N, const double *ALPHA, const double *A, const int *LDA, const double *X, const int *incX, const double *BETA, const double *Y, const int *incY) cdef dgemv_ptr dgemv=<dgemv>PyCObject_AsVoidPtr(fblas.dgemv._cpointer) # matrix vector multiplication
But I need help (a) defining the actual function that I can use in Python (i.e. a
vec-matrix function analogous to
vec_vec above), and (b) knowing how to use it to properly replicate the behavior of
np.inner, which is what I need for the model I'm implementing.
Edit: Here is the link to relevant BLAS documentation for dgemv, that I need to be using, which is confirmed here:
In : np.allclose(scipy.linalg.blas.fblas.dgemv(1.0,y,x), np.inner(x,y)) Out: True
But using it out of the box like this is actually slower than pure np.inner, so I still need help with the Cython implementation.
Edit2 Here's my latest attempt at this, which compiles fine but crashes python with a segmentation fault whenever I try to run it:
cdef int ONE = 1 cdef char tr = 'n' cdef REAL_t ZEROF = <REAL_t>0.0 cdef REAL_t ONEF = <REAL_t>1.0 def mat_vec(mat,vec,mat_rows,mat_cols): cdef int m = mat_rows cdef int n = mat_cols out = <REAL_t>dgemv(&tr, &m, &n, &ONEF, <REAL_t *>(np.PyArray_DATA(mat)), &m, <REAL_t *>(np.PyArray_DATA(vec)), &ONE, &ZEROF, NULL, &ONE) return out
After compiling, I try to run
linalg.mat_vec(y,x,5,5), (using the same x and y as above) but this just crashes. I think I'm close, but don't know what else to change...