I was trying to figure out the fastest way to do matrix multiplication and tried 3 different ways:

- Pure python implementation: no surprises here.
- Numpy implementation using
`numpy.dot(a, b)`

- Interfacing with C using
`ctypes`

module in Python.

This is the C code that is transformed into a shared library:

```
#include <stdio.h>
#include <stdlib.h>
void matmult(float* a, float* b, float* c, int n) {
int i = 0;
int j = 0;
int k = 0;
/*float* c = malloc(nay * sizeof(float));*/
for (i = 0; i < n; i++) {
for (j = 0; j < n; j++) {
int sub = 0;
for (k = 0; k < n; k++) {
sub = sub + a[i * n + k] * b[k * n + j];
}
c[i * n + j] = sub;
}
}
return ;
}
```

And the Python code that calls it:

```
def C_mat_mult(a, b):
libmatmult = ctypes.CDLL("./matmult.so")
dima = len(a) * len(a)
dimb = len(b) * len(b)
array_a = ctypes.c_float * dima
array_b = ctypes.c_float * dimb
array_c = ctypes.c_float * dima
suma = array_a()
sumb = array_b()
sumc = array_c()
inda = 0
for i in range(0, len(a)):
for j in range(0, len(a[i])):
suma[inda] = a[i][j]
inda = inda + 1
indb = 0
for i in range(0, len(b)):
for j in range(0, len(b[i])):
sumb[indb] = b[i][j]
indb = indb + 1
libmatmult.matmult(ctypes.byref(suma), ctypes.byref(sumb), ctypes.byref(sumc), 2);
res = numpy.zeros([len(a), len(a)])
indc = 0
for i in range(0, len(sumc)):
res[indc][i % len(a)] = sumc[i]
if i % len(a) == len(a) - 1:
indc = indc + 1
return res
```

I would have bet that the version using C would have been faster ... and I'd have lost ! Below is my benchmark which seems to show that I either did it incorrectly, or that `numpy`

is stupidly fast:

I'd like to understand why the `numpy`

version is faster than the `ctypes`

version, I'm not even talking about the pure Python implementation since it is kind of obvious.

`b[k * n + j];`

inside the inner loop (over`k`

) has a stride of`n`

, so it touches a different cache line on every access. And your loop can't auto-vectorize with SSE/AVX.Solve this by transposingThat would still be a naive implementation without cache-blocking (aka loop tiling), though.`b`

up-front, which costs O(n^2) time and pays for itself in reduced cache misses while you do O(n^3) loads from`b`

.`int sum`

(for some reason...), your loop could actually vectorize without`-ffast-math`

if the inner loop was accessing two sequential arrays. FP math is not associative, so compilers can't re-order operations without`-ffast-math`

, but integer math is associative (and has lower latency than FP addition, which helps if you're not going to optimize your loop with multiple accumulators or other latency hiding stuff).`float`

->`int`

conversion costs about the same as an FP`add`

(actually using the FP add ALU on Intel CPUs), so it's not worth it in optimized code.