Your approach is correct, but as you note, it is way too slow for the task at hand. Consider how large your task is in the numerically best implementation (not bothering about boundary values):

```
def kurt(X, w):
n, m = X.shape
K = np.zeros_like(X)
for i in xrange(w, n-w): # 5000 iterations
for j in xrange(w, m-w): # 5000 iterations
x = X[i-w:i+w+1,j-w:j+w+1].flatten() # copy 25*25=625 values
x -= x.mean() # calculate and subtract mean
x /= np.sqrt((x**2).mean()) # normalize by stddev (625 mult.)
K[i,j] = (x**4).mean() - 3. # 2*625 = 1250 multiplications
return K
```

So we have `5000*5000*1875 ~ 47 billion`

(!) multiplications. This will even be too slow to be useful in a plain C implementation, let alone by passing a Python function `kurtosis()`

to the inner loop of `generic_filter()`

. The latter is actually calling a C extension function, but there are negligible benefits since it must call back into Python at each iteration, which is very expensive.

So, the actual problem is that you need a better algorithm. Since scipy doesn't have it, let's develop it step by step here.

The key observation that permits acceleration of this problem is that the kurtosis calculations for successive windows are based on mostly the same values, except one row (25 values) which is replaced. So, instead of recalculating the kurtosis from scratch using all 625 values, we attempt to keep track of previously calculated sums and update them such that only the 25 new values need to be processed.

This requires expanding the `(x - mu)**4`

factor, since only the running sums over `x`

, `x**2`

, `x**3`

and `x**4`

can be easily updated. There is no nice cancellation as in the formula for the standard deviation that you mentioned, but it is entirely feasible:

```
def kurt2(X, w):
n, m = X.shape
K = np.zeros_like(X)
W = 2*w + 1
for j in xrange(m-W+1):
for i in xrange(n-W+1):
x = X[i:i+W,j:j+W].flatten()
x2 = x*x
x3 = x2*x
x4 = x2*x2
M1 = x.mean()
M2 = x2.mean()
M3 = x3.mean()
M4 = x4.mean()
M12 = M1*M1
V = M2 - M12;
K[w+i,w+j] = (M4 - 4*M1*M3 + 3*M12*(M12 + 2*V)) / (V*V) - 3
return K
```

**Note:** *The algorithm written in this form is numerically less stable, since we let numerator and denominator become individually very large, while previously we were dividing early to prevent this (even at the cost of a sqrt). However, I found that for the kurtosis this was never an issue for practical applications.*

In the code above, I have tried to minimize the number of multiplications. The *running means* `M1`

, `M2`

, `M3`

and `M4`

can now be updated rather easily, by subtracting the contributions of the row that is no longer part of the window and adding the contributions of the new row.

Let's implement this:

```
def kurt3(X, w):
n, m = X.shape
K = np.zeros_like(X)
W = 2*w + 1
N = W*W
Xp = np.zeros((4, W, W), dtype=X.dtype)
xp = np.zeros((4, W), dtype=X.dtype)
for j in xrange(m-W+1):
# reinitialize every time we reach row 0
Xp[0] = x1 = X[:W,j:j+W]
Xp[1] = x2 = x1*x1
Xp[2] = x3 = x2*x1
Xp[3] = x4 = x2*x2
s = Xp.sum(axis=2) # make sure we sum along the fastest index
S = s.sum(axis=1) # the running sums
s = s.T.copy() # circular buffer of row sums
M = S / N
M12 = M[0]*M[0]
V = M[1] - M12;
# kurtosis at row 0
K[w,w+j] = (M[3] - 4*M[0]*M[2] + 3*M12*(M12 + 2*V)) / (V*V) - 3
for i in xrange(n-W):
xp[0] = x1 = X[i+W,j:j+W] # the next row
xp[1] = x2 = x1*x1
xp[2] = x3 = x2*x1
xp[3] = x4 = x2*x2
k = i % W # index in circular buffer
S -= s[k] # remove cached contribution of old row
s[k] = xp.sum(axis=1) # cache new row
S += s[k] # add contributions of new row
M = S / N
M12 = M[0]*M[0]
V = M[1] - M12;
# kurtosis at row != 0
K[w+1+i,w+j] = (M[3] - 4*M[0]*M[2] + 3*M12*(M12 + 2*V)) / (V*V) - 3
return K
```

Now that we have a good algorithm, we note that the timing results are still rather disappointing. Our problem is now that Python + numpy is the wrong language for such a number crunching job. Let's write a C extension! Here is `_kurtosismodule.c`

:

```
#include <Python.h>
#include <numpy/arrayobject.h>
static inline void add_line(double *b, double *S, const double *x, size_t W) {
size_t l;
double x1, x2;
b[0] = b[1] = b[2] = b[3] = 0.;
for (l = 0; l < W; ++l) {
b[0] += x1 = x[l];
b[1] += x2 = x1*x1;
b[2] += x2*x1;
b[3] += x2*x2;
}
S[0] += b[0];
S[1] += b[1];
S[2] += b[2];
S[3] += b[3];
}
static PyObject* py_kurt(PyObject* self, PyObject* args) {
PyObject *objK, *objX, *objB;
int w;
PyArg_ParseTuple(args, "OOOi", &objK, &objX, &objB, &w);
double *K = PyArray_DATA(objK);
double *X = PyArray_DATA(objX);
double *B = PyArray_DATA(objB);
size_t n = PyArray_DIM(objX, 0);
size_t m = PyArray_DIM(objX, 1);
size_t W = 2*w + 1, N = W*W, i, j, k, I, J;
double *S = B + 4*W;
double *x, *b, M, M2, V;
for (j = 0, J = m*w + w; j < m-W+1; ++j, ++J) {
S[0] = S[1] = S[2] = S[3] = 0.;
for (k = 0, x = X + j, b = B; k < W; ++k, x += m, b += 4) {
add_line(b, S, x, W);
}
M = S[0] / N;
M2 = M*M;
V = S[1] / N - M2;
K[J] = ((S[3] - 4*M*S[2]) / N + 3*M2*(M2 + 2*V)) / (V*V) - 3;
for (i = 0, I = J + m; i < n-W; ++i, x += m, I += m) {
b = B + 4*(i % W); // row in circular buffer
S[0] -= b[0];
S[1] -= b[1];
S[2] -= b[2];
S[3] -= b[3];
add_line(b, S, x, W);
M = S[0] / N;
M2 = M*M;
V = S[1] / N - M2;
K[I] = ((S[3] - 4*M*S[2]) / N + 3*M2*(M2 + 2*V)) / (V*V) - 3;
}
}
Py_RETURN_NONE;
}
static PyMethodDef methods[] = {
{"kurt", py_kurt, METH_VARARGS, ""},
{0}
};
PyMODINIT_FUNC init_kurtosis(void) {
Py_InitModule("_kurtosis", methods);
import_array();
}
```

Build with:

```
python setup.py build_ext --inplace
```

where `setup.py`

is:

```
from distutils.core import setup, Extension
module = Extension('_kurtosis', sources=['_kurtosismodule.c'])
setup(ext_modules=[module])
```

Note that we don't allocate any memory in the C extension. This way, we don't have to get into any mess with reference counts/garbage collection. We just use an entry point in Python:

```
import _kurtosis
def kurt4(X, w):
# add type/size checking if you like
K = np.zeros(X.shape, np.double)
scratch = np.zeros(8*(w + 1), np.double)
_kurtosis.kurt(K, X, scratch, w)
return K
```

Finally, let's do the timing:

```
In [1]: mat = np.random.random_sample((5000, 5000))
In [2]: %timeit K = kurt4(mat, 12) # 2*12 + 1 = 25
1 loops, best of 3: 5.25 s per loop
```

A very reasonable performance given the size of the task!

`pandas`

has a rolling kurtosis function, pd.stats.moments.rolling_kurt`, but the implementation doesn't do a good job of being stable either, and it only works along a single dimension... – Jaime Jun 18 '14 at 23:29