I am using several techniques (**NumPy**, **Weave** and **Cython**) to perform a Python performance benchmark. What the code basically does mathematically is `C = AB`

, where A, B and C are `N x N`

matrices (**NOTE:** this is a matrix product and not an element-wise multiplication).

I have written 5 distinct implementations of the code:

- Pure python (Loop over 2D Python lists)
- NumPy (Dot product of 2D NumPy arrays)
- Weave inline (C++ loop over 2D arrays)
- Cython (Loop over 2D Python lists + static typing)
- Cython-Numpy (Loop over 2D NumPy arrays + static typing)

My expectation is that implementations 2 through 5 will be substantially faster than implementation 1. My results however indicate otherwise. These are my normalised speed-up results relative to the pure Python implementation:

- python_list: 1.00
- numpy_array: 330.09
- weave_inline: 30.72
- cython_list: 2.80
- cython_array: 0.14

I am quite happy with the performance of NumPy, however I am less enthusiastic about Weave's performance and Cython's performance makes me cry. My entire code is separated over two files. Everything is automated and you simply need to run the first file to see all results. Could someone please aid me by indicating what I could do to obtain better results?

**matmul.py:**

```
import time
import numpy as np
from scipy import weave
from scipy.weave import converters
import pyximport
pyximport.install()
import cython_matmul as cml
def python_list_matmul(A, B):
C = np.zeros(A.shape, dtype=float).tolist()
A = A.tolist()
B = B.tolist()
for k in xrange(len(A)):
for i in xrange(len(A)):
for j in xrange(len(A)):
C[i][k] += A[i][j] * B[j][k]
return C
def numpy_array_matmul(A, B):
return np.dot(A, B)
def weave_inline_matmul(A, B):
code = """
int i, j, k;
for (k = 0; k < N; ++k)
{
for (i = 0; i < N; ++i)
{
for (j = 0; j < N; ++j)
{
C(i, k) += A(i, j) * B(j, k);
}
}
}
"""
C = np.zeros(A.shape, dtype=float)
weave.inline(code, ['A', 'B', 'C', 'N'], type_converters=converters.blitz, compiler='gcc')
return C
N = 100
A = np.random.rand(N, N)
B = np.random.rand(N, N)
function = []
function.append([python_list_matmul, 'python_list'])
function.append([numpy_array_matmul, 'numpy_array'])
function.append([weave_inline_matmul, 'weave_inline'])
function.append([cml.cython_list_matmul, 'cython_list'])
function.append([cml.cython_array_matmul, 'cython_array'])
t = []
for i in xrange(len(function)):
t1 = time.time()
C = function[i][0](A, B)
t2 = time.time()
t.append(t2 - t1)
print function[i][1] + ' \t: ' + '{:10.6f}'.format(t[0] / t[-1])
```

**cython_matmul.pyx:**

```
import numpy as np
cimport numpy as np
import cython
cimport cython
DTYPE = np.float
ctypedef np.float_t DTYPE_t
@cython.boundscheck(False)
@cython.wraparound(False)
@cython.nonecheck(False)
cpdef cython_list_matmul(A, B):
cdef int i, j, k
cdef int N = len(A)
A = A.tolist()
B = B.tolist()
C = np.zeros([N, N]).tolist()
for k in xrange(N):
for i in xrange(N):
for j in xrange(N):
C[i][k] += A[i][j] * B[j][k]
return C
@cython.boundscheck(False)
@cython.wraparound(False)
@cython.nonecheck(False)
cpdef cython_array_matmul(np.ndarray[DTYPE_t, ndim=2] A, np.ndarray[DTYPE_t, ndim=2] B):
cdef int i, j, k, N = A.shape[0]
cdef np.ndarray[DTYPE_t, ndim=2] C = np.zeros([N, N], dtype=DTYPE)
for k in xrange(N):
for i in xrange(N):
for j in xrange(N):
C[i][k] += A[i][j] * B[j][k]
return C
```

`weave`

as during that first computation,`weave`

needs to actually compile the inline code -- Subsequent calls will likely bypass this really expensive step because I think the inline code will be cached. – mgilson Jun 10 '13 at 15:39`np.import_array()`

would allow you to use Numpy's C API and call`np.PyArray_MatrixProduct2(A, B, C)`

instead of performing your looping. (Or would that obviate the need for your cython function to begin with?) Using`np.matrix`

instead of`np.ndarray`

may affect performance as well but I'm not sure how much. – JAB Aug 15 '13 at 15:20