def numpy2pink(array):
"""
Makes an image from a numpy array
"""
## Not elegant
if (np.size(array.shape) == 2):
Image = {
'uint8_t': pink.char_image([array.shape[1], array.shape[0]]),
'uint16_t': pink.short_image([array.shape[1], array.shape[0]]),
'int32_t': pink.int_image([array.shape[1], array.shape[0]]),
'float': pink.float_image([array.shape[1], array.shape[0]]),
'double': pink.double_image([array.shape[1], array.shape[0]]),
}
elif (np.size(array.shape) == 3):
Image = {
'uint8_t':
pink.char_image([array.shape[2], array.shape[1], array.shape[0]]),
'uint16_t':
pink.short_image([array.shape[2], array.shape[1], array.shape[0]]),
'int32_t':
pink.int_image([array.shape[2], array.shape[1], array.shape[0]]),
'float':
pink.float_image([array.shape[2], array.shape[1], array.shape[0]]),
'double':
pink.double_image([array.shape[2], array.shape[1],
array.shape[0]]),
}
else:
sys.stder.write("Number of dimensions not supported\n")
return None
myimg = Image.get(np2pinkdtype[array.dtype])
# copy data
myimg.set_pixels(array.ctypes.data, array.nbytes)
return myimg
def array_2_image(arr):
S = list(arr.shape)
N = arr.size
img = pink.char_image(S)
arr.resize(N)
for i in range(N):
img[i] = int(arr[i])
return img
def disk_structuring_element(radius):
d = radius + radius + 1
res = pink.char_image([d, d])
res.fill(0)
res.center = [radius, radius]
res[[radius, radius]] = 255
res = pink.dilatball(res, radius)
return (res)
def extract_cells(image, threshold=24):
# creating the structuring element
elem = pink.char_image([3, 3])
elem.fill(1)
elem.center = [1, 1]
grad = pink.gradmorph(muscle, elem)
seuil = pink.seuil(grad, threshold)
frame = pink.frame(pink.char_image(image.size), 255)
dilated = pink.geodilat(frame, seuil, 8)
skeleton = pink.skeleton(dilated, 0, 8)
inv = pink.inverse(skeleton)
eroded = pink.erosball(inv, 5)
inv = pink.inverse(eroded)
skeleton2 = pink.skeleton(inv, image, 4)
return skeleton2
def correct_bias(image, xc, yc, alpha):
result = pink.char_image([0, 0])
result.copy(image)
rs = result.size[0]
cs = result.size[1]
for y in range(cs):
for x in range(rs):
R = pow((xc - x) * (xc - x) + (yc - y) * (yc - y), 0.5)
T = (1.0 * result[[x, y]]) - (alpha * R)
if T > 255:
T = 255
if T < 0:
T = 0
result[[x, y]] = int(round(T))
return (result)
def find_bias(image, xc, yc):
rs = image.size[0]
cs = image.size[1]
circle = pink.char_image(image.size)
rad = 20 # below, circles are too small
Y = []
while True:
if debug:
print rad
if (xc + rad >= rs) or (xc - rad < 0):
break
if (yc + rad >= cs) or (yc - rad < 0):
break
circle = pink.drawball(circle, rad, xc, yc, 0)
circle = pink.border(circle, 8)
av = pink.average(image, circle)
Y = Y + [av]
rad = rad + 1
X = range(len(Y))
res = pink.identifyline(X, Y)
# output : coefficient a of the equation of the line y = ax+b
# matching the data
return(res[0])
#ex 4
## filtering and inverting
circuit = pink.readimage("../images/circuit.pgm")
inv = pink.inverse(circuit)
inv = pink.seuil(inv, 180, 0, 255)
inv = filter_noise(inv)
viewer2 = Imview(inv)
#inv.writeimage("circ.pgm")
# Filtering out the strips to get the round ends
round = pink.openball(inv, 5, 0)
# plus one round of geodesic dilation to get the shape back
roundok = pink.geodilat(round, inv, 8, 1) # note the 1 here
viewer2.show(roundok, "roundok")
# get the strips by difference
strips = inv - roundok
viewer2.show(strips, "strips")
## dilation
structuring_element = pink.char_image([11, 1])
structuring_element.fill(255)
structuring_element.writeimage("se.pgm")
structuring_element.center = [5, 0]
dilated = pink.dilation(inv, structuring_element)
#dilated.writeimage("dil.pgm")
viewer2.show(dilated, "dilated")
# LuM end of file
def fill_the_hole(image, tbmin=1, tbmax=1):
frame = pink.frame(pink.char_image(image.size), 255)
dist = pink.dist(image, 0)
return pink.toposhrink(inv(frame), inv(dist), 26, tbmin, tbmax, 1, 1,
image)
from pink import cpp as pink
# ex 4.1
numbers = pink.readimage("../images/numbers.pgm")
ball = pink.genball(5)
openn = pink.opening(numbers, ball)
normalized = pink.seuil(numbers - openn, 10, 0, 255)
normalized.writeimage("normalized.pgm")
# ex 5.1-1
cell = pink.readimage("../images/cell.pgm")
ball = pink.genball(1)
dcell = pink.dilation(cell, ball)
ecell = pink.erosion(cell, ball)
pink.normalize(dcell - ecell).writeimage("grad.pgm")
# ex 5.1-2
## HELP ME!!!
#ex 6.1-1
bloodcells = pink.readimage("../images/bloodcells.pgm")
marker = pink.char_image(bloodcells.size)
marker[[50, 50]] = 255
marker.writeimage("marker.pgm")
ws = pink.watershed(bloodcells, marker, 8)
ws.writeimage("ws.pgm")
# LuM end of file
def fill_the_holes(image):
frame = pink.frame(pink.char_image(image.size), 255)
inv = pink.inverse(image)
dilated = pink.geodilat(frame, inv, 8)
result = pink.inverse(dilated)
return result
def remove_objects(image):
frame = pink.frame(pink.char_image(image.size), 255)
border_objects = pink.geodilat(frame, image, 8)
result = image - border_objects
return result
def crop(image, x, y, w, h):
res = pink.char_image([w, h])
res = pink.insert_image(res, image, [-x, -y])
return (res)
RS = 4 # numbers of tiles in a row
CS = 4 # numbers of tiles in a column
rs = 100 # row size for a tile
cs = 100 # column size for a tile
nb_grains = 0
grain_size = 0
for J in range(CS):
for I in range(RS):
filename = 'tile%02d.pgm' % (J * CS + I)
tile = pink.readimage(filename)
# separate objects into interior and border objects
frame = pink.frame(pink.char_image(tile.size), 255)
border_objects = pink.geodilat(frame, tile, 8)
interior_objects = tile - border_objects
# measure interior objects
grain_size = grain_size + pink.area(interior_objects)
lab = pink.labelfgd(interior_objects, 8)
nb_grains = nb_grains + pink.minmax(lab)[1]
if DEBUG:
print("I,J,s,n: " + str(I) + " " + str(J) + " " + str(grain_size) +
" " + str(nb_grains))
# deal with border objects
if (I < RS - 1) and (J < CS - 1):
filename_r = 'tile%02d.pgm' % (J * CS + I + 1)
tile_r = pink.readimage(filename_r)
filename_d = 'tile%02d.pgm' % ((J + 1) * CS + I)
tile_d = pink.readimage(filename_d)
if debug:
view3d(carotide, dilated)
diff = carotide - dilated
seuil = pink.seuil(diff, 94)
if debug:
view3d(carotide, seuil)
component = pink.selectcomp(seuil, 26, 58, 46, 0)
if debug:
view3d(carotide, component)
carotide_seg = component
### the skeleton operator
axonepair = pink.readimage("../images/axonepair.pgm")
#imview(axonepair) ## HUGUES WRITE ME!
blank = pink.char_image(axonepair.size)
skeleton = pink.skeleton(axonepair, blank, 8)
#imview(skeleton)
pink.surimp(axonepair, skeleton, "axoskel.ppm")
### distances
dist = pink.distc(axonepair, 4)
dist.writeimage("imagea.pgm")
### randrgb will be replaced with imview colourmap (rand rgb)
dist = pink.distc(axonepair, 8)
dist.writeimage("imageb.pgm")
dist = pink.distc(axonepair, 0)
dist.writeimage("imagec.pgm")
### skeletons guided by a priority image
image.fill(0)
rs = image.size[0]
cs = image.size[1]
for j in range(margin, cs-margin):
for i in range(margin, rs-margin):
if random.random() <= p:
image[[i,j]] = 255
rad = 4 # radius of particles
RS = 4 # numbers of tiles in a row
CS = 4 # numbers of tiles in a column
rs = 100 # row size for a tile
cs = 100 # column size for a tile
pr = 0.0004 # proportion of particle centers
img = pink.char_image([RS*rs,CS*cs])
randimage2(img, pr, rad+1)
img = pink.dilatball(img, rad)
img.writeimage("wholeimage.pgm")
imview(img)
grain_size = pink.area(img)
lab = pink.labelfgd(img, 8)
nb_grains = pink.minmax(lab)[1]
print("grain_size = " + str(grain_size))
print("nb_grains = " + str(nb_grains))
img = pink.readimage("wholeimage.pgm")
tile = pink.char_image([rs,cs])
for J in range(CS):
