connecting_the_dots/data/lcn/lcn.pyx

import numpy as np
cimport cython

# use c square root function
cdef extern from "math.h":
    float sqrt(float x)

@cython.boundscheck(False)
@cython.wraparound(False)
@cython.cdivision(True)

# 3 parameters:
# - float image
# - kernel size (actually this is the radius, kernel is 2*k+1)
# - small constant epsilon that is used to avoid division by zero
def normalize(float[:, :] img, int kernel_size = 4, float epsilon = 0.01):
    
    # image dimensions
    cdef Py_ssize_t M = img.shape[0]
    cdef Py_ssize_t N = img.shape[1]

    # create outputs and output views
    img_lcn  = np.zeros((M, N), dtype=np.float32)
    img_std  = np.zeros((M, N), dtype=np.float32)
    cdef float[:, :] img_lcn_view  = img_lcn
    cdef float[:, :] img_std_view  = img_std
    
    # temporary c variables
    cdef float tmp, mean, stddev
    cdef Py_ssize_t m, n, i, j
    cdef Py_ssize_t ks = kernel_size
    cdef float eps = epsilon
    cdef float num = (ks*2+1)**2

    # for all pixels do
    for m in range(ks,M-ks):
        for n in range(ks,N-ks):
            
            # calculate mean
            mean = 0;
            for i in range(-ks,ks+1):
                for j in range(-ks,ks+1):
                    mean += img[m+i, n+j]
            mean = mean/num
        
            # calculate std dev
            stddev = 0;
            for i in range(-ks,ks+1):
                for j in range(-ks,ks+1):
                    stddev = stddev + (img[m+i, n+j]-mean)*(img[m+i, n+j]-mean)
            stddev = sqrt(stddev/num)

            # compute normalized image (add epsilon) and std dev image
            img_lcn_view[m, n]  = (img[m, n]-mean)/(stddev+eps)
            img_std_view[m, n]  = stddev

    # return both
    return img_lcn, img_std
init 6 years ago			`import numpy as np`
			`cimport cython`

			`# use c square root function`
			`cdef extern from "math.h":`
			`float sqrt(float x)`

			`@cython.boundscheck(False)`
			`@cython.wraparound(False)`
			`@cython.cdivision(True)`

			`# 3 parameters:`
			`# - float image`
			`# - kernel size (actually this is the radius, kernel is 2*k+1)`
			`# - small constant epsilon that is used to avoid division by zero`
			`def normalize(float[:, :] img, int kernel_size = 4, float epsilon = 0.01):`

			`# image dimensions`
			`cdef Py_ssize_t M = img.shape[0]`
			`cdef Py_ssize_t N = img.shape[1]`

			`# create outputs and output views`
			`img_lcn = np.zeros((M, N), dtype=np.float32)`
			`img_std = np.zeros((M, N), dtype=np.float32)`
			`cdef float[:, :] img_lcn_view = img_lcn`
			`cdef float[:, :] img_std_view = img_std`

			`# temporary c variables`
			`cdef float tmp, mean, stddev`
			`cdef Py_ssize_t m, n, i, j`
			`cdef Py_ssize_t ks = kernel_size`
			`cdef float eps = epsilon`
			`cdef float num = (ks2+1)*2`

			`# for all pixels do`
			`for m in range(ks,M-ks):`
			`for n in range(ks,N-ks):`

			`# calculate mean`
			`mean = 0;`
			`for i in range(-ks,ks+1):`
			`for j in range(-ks,ks+1):`
			`mean += img[m+i, n+j]`
			`mean = mean/num`

			`# calculate std dev`
			`stddev = 0;`
			`for i in range(-ks,ks+1):`
			`for j in range(-ks,ks+1):`
			`stddev = stddev + (img[m+i, n+j]-mean)*(img[m+i, n+j]-mean)`
			`stddev = sqrt(stddev/num)`

			`# compute normalized image (add epsilon) and std dev image`
			`img_lcn_view[m, n] = (img[m, n]-mean)/(stddev+eps)`
			`img_std_view[m, n] = stddev`

			`# return both`
			`return img_lcn, img_std`