# Wrapping a LAPACKE function using Cython

I'm trying to wrap the LAPACK function `dgtsv` (a solver for tridiagonal systems of equations) using Cython.

I came across this previous answer, but since `dgtsv` is not one of the LAPACK functions that are wrapped in `scipy.linalg` I don't think I can use this particular approach. Instead I've been trying to follow this example.

Here's the contents of my `lapacke.pxd` file:

``````ctypedef int lapack_int

cdef extern from "lapacke.h" nogil:

int LAPACK_ROW_MAJOR
int LAPACK_COL_MAJOR

lapack_int LAPACKE_dgtsv(int matrix_order,
lapack_int n,
lapack_int nrhs,
double * dl,
double * d,
double * du,
double * b,
lapack_int ldb)
``````

...here's my thin Cython wrapper in `_solvers.pyx`:

``````#!python

cimport cython
from lapacke cimport *

cpdef TDMA_lapacke(double[::1] DL, double[::1] D, double[::1] DU,
double[:, ::1] B):

cdef:
lapack_int n = D.shape[0]
lapack_int nrhs = B.shape[1]
lapack_int ldb = B.shape[0]
double * dl = &DL[0]
double * d = &D[0]
double * du = &DU[0]
double * b = &B[0, 0]
lapack_int info

info = LAPACKE_dgtsv(LAPACK_ROW_MAJOR, n, nrhs, dl, d, du, b, ldb)

return info
``````

...and here's a Python wrapper and test script:

``````import numpy as np
from scipy import sparse
from cymodules import _solvers

def trisolve_lapacke(dl, d, du, b, inplace=False):

if (dl.shape[0] != du.shape[0] or dl.shape[0] != d.shape[0] - 1
or b.shape != d.shape):
raise ValueError('Invalid diagonal shapes')

if b.ndim == 1:
# b is (LDB, NRHS)
b = b[:, None]

# be sure to force a copy of d and b if we're not solving in place
if not inplace:
d = d.copy()
b = b.copy()

# this may also force copies if arrays are improperly typed/noncontiguous
dl, d, du, b = (np.ascontiguousarray(v, dtype=np.float64)
for v in (dl, d, du, b))

# b will now be modified in place to contain the solution
info = _solvers.TDMA_lapacke(dl, d, du, b)
print info

return b.ravel()

def test_trisolve(n=20000):

dl = np.random.randn(n - 1)
d = np.random.randn(n)
du = np.random.randn(n - 1)

M = sparse.diags((dl, d, du), (-1, 0, 1), format='csc')
x = np.random.randn(n)
b = M.dot(x)

x_hat = trisolve_lapacke(dl, d, du, b)

print "||x - x_hat|| = ", np.linalg.norm(x - x_hat)
``````

Unfortunately, `test_trisolve` just segfaults on the call to `_solvers.TDMA_lapacke`. I'm pretty sure my `setup.py` is correct - `ldd _solvers.so` shows that `_solvers.so` is being linked to the correct shared libraries at runtime.

I'm not really sure how to proceed from here - any ideas?

A brief update:

for smaller values of `n` I tend not to get segfaults immediately, but I do get nonsense results (||x - x_hat|| ought to be very close to 0):

``````In [28]: test_trisolve2.test_trisolve(10)
0
||x - x_hat|| =  6.23202576396

In [29]: test_trisolve2.test_trisolve(10)
-7
||x - x_hat|| =  3.88623414288

In [30]: test_trisolve2.test_trisolve(10)
0
||x - x_hat|| =  2.60190676562

In [31]: test_trisolve2.test_trisolve(10)
0
||x - x_hat|| =  3.86631743386

In [32]: test_trisolve2.test_trisolve(10)
Segmentation fault
``````

Usually `LAPACKE_dgtsv` returns with code `0` (which should indicate success), but occasionally I get `-7`, which means that argument 7 (`b`) had an illegal value. What's happening is that only the first value of `b` is actually being modified in place. If I keep on calling `test_trisolve` I will eventually hit a segfault even when `n` is small.

-

OK, I figured it out eventually - it seems I've misunderstood what row- and column-major refer to in this case.

Since C-contiguous arrays follow row-major order, I assumed that I ought to specify `LAPACK_ROW_MAJOR` as the first argument to `LAPACKE_dgtsv`.

In fact, if I change

``````info = LAPACKE_dgtsv(LAPACK_ROW_MAJOR, ...)
``````

to

``````info = LAPACKE_dgtsv(LAPACK_COL_MAJOR, ...)
``````

then my function works:

``````test_trisolve2.test_trisolve()
0
||x - x_hat|| =  6.67064747632e-12
``````

This seems pretty counter-intuitive to me - can anyone explain why this is the case?

-