Uwimg is a C package for images processing that is callable in Python. It's an assignment of The Ancient Secrets of Computer vision CSE 455
Table Content
- Installation
- Basic Level Of Image Processing
- Middle Level Of Image Processing
- Panorama
- Optical Flow
- Neural Network
$git clone https://github.com/DiaaZiada/Uwimg
$cd Uwimg
$makeOriginal Image
Getting pixel value
from uwimg import *
im = load_image("data/dog.jpg")
pixel = get_pixel(im, 0, 0, 0)
print(pixel)=> 0.0470588244497776 Setting pixel to a value
from uwimg import *
# remove all red colors from the image
im = load_image("data/dog.jpg")
for row in range(im.h):
for col in range(im.w):
set_pixel(im, col, row, 0, 0)
save_image(im, "output/no_red_dog")
from uwimg import *
im = load_image("data/dog.jpg")
im2 = copy_image(im) from uwimg import *
im = load_image("data/dog.jpg")
graybar = rgb_to_grayscale(im)
save_image(graybar, "output/gray_dog")
from uwimg import *
im = load_image("data/dog.jpg")
shift_image(im, 0, .4)
shift_image(im, 1, .4)
shift_image(im, 2, .4)
save_image(im, "output/shifted_dog")
from uwimg import *
im = load_image("data/dog.jpg")
shift_image(im, 0, .4)
shift_image(im, 1, .4)
shift_image(im, 2, .4)
clamp_image(im)
save_image(im, "output/ligth_fixed_dog")
from uwimg import *
im = load_image("data/dog.jpg")
rgb_to_hsv(im)
shift_image(im, 1, .2)
clamp_image(im)
hsv_to_rgb(im)
save_image(im, "output/rgb_hsv_rgb_dog")
Nearest Neighbor
from uwimg import *
im = load_image("data/dog.jpg")
a = nn_resize(im, im.w*4, im.h*4)
save_image(a, "output/4x_nn_dog")
Bilinear
from uwimg import *
im = load_image("data/dog.jpg")
a = bilinear_resize(im, im.w*4, im.h*4)
save_image(a, "output/4x_bl_dog")
Nearest Neighbor
from uwimg import *
im = load_image("data/dog.jpg")
a = nn_resize(im, im.w//7, im.h//7)
save_image(a, "output/7th-nn_dog")
Bilinear
from uwimg import *
im = load_image("data/dog.jpg")
a = bilinear_resize(im, im.w//7, im.h//7)
save_image(a, "output/7th-bl_dog")
from uwimg import *
im = load_image("data/dog.jpg")
f = make_box_filter(7)
blur = convolve_image(im, f, 1)
save_image(blur, "output/box7_dog")
from uwimg import *
im = load_image("data/dog.jpg")
f = make_box_filter(7)
blur = convolve_image(im, f, 1)
thumb = nn_resize(blur, blur.w//7, blur.h//7)
save_image(thumb, "output/thumb_dog")
from uwimg import *
im = load_image("data/dog.jpg")
f = make_gaussian_filter(2)
blur = convolve_image(im, f, 1)
save_image(blur, "output/gauss2_dog")
from uwimg import *
im = load_image("data/dog.jpg")
f = make_gaussian_filter(2)
lfreq = convolve_image(im, f, 1)
hfreq = im - lfreq
reconstruct = lfreq + hfreq
save_image(lfreq, "output/low_frequency_dog.jpg")
save_image(hfreq, "output/high_frequency_dog.jpg")
save_image(reconstruct, "output/reconstruct_dog.jpg")low frequency
high frequency
reconstruct
from uwimg import *
im = load_image("data/dog.jpg")
res = sobel_image(im)
mag = res[0]
feature_normalize(mag)
save_image(mag, "output/magnitude")
from uwimg import *
im = load_image("data/dog.jpg")
res = sobel_image(im)
mag = res[0]
feature_normalize(mag)
img = colorize_sobel(im)
save_image(img, "output/colored_magnitude_dog")
from uwimg import *
im = load_image("data/Rainier1.png")
detect_and_draw_corners(im, 2, 50, 3)
save_image(im, "output/corners")
from uwimg import *
a = load_image("data/Rainier1.png")
b = load_image("data/Rainier2.png")
m = find_and_draw_matches(a, b, 2, 50, 3)
save_image(m, "output/matches")
from uwimg import *
im1 = load_image("data/Rainier1.png")
im2 = load_image("data/Rainier2.png")
pan = panorama_image(im1, im2, thresh=50)
save_image(pan, "output/easy_panorama")
Final panorama image
from uwimg import *
a = load_image("data/dog_a.jpg")
b = load_image("data/dog_b.jpg")
flow = optical_flow_images(b, a, 15, 8)
draw_flow(a, flow, 8)
save_image(a, "output/optical-flow")image a
image b
optical flow
wget https://pjreddie.com/media/files/mnist_train.tar.gz
wget https://pjreddie.com/media/files/mnist_test.tar.gz
tar xzf mnist_train.tar.gz
tar xzf mnist_test.tar.gzfrom uwimg import *
def softmax_model(inputs, outputs):
l = [make_layer(inputs, outputs, SOFTMAX)]
return make_model(l)
def neural_net(inputs, outputs):
print(inputs)
l = [ make_layer(inputs, 32, LOGISTIC),
make_layer(32, outputs, SOFTMAX)]
return make_model(l)
print("loading data...")
train = load_classification_data("mnist.train", "mnist.labels", 1)
test = load_classification_data("mnist.test", "mnist.labels", 1)
print("done")
print
print("training model...")
batch = 128
iters = 1000
rate = .01
momentum = .9
decay = .0
m = softmax_model(train.X.cols, train.y.cols)
train_model(m, train, batch, iters, rate, momentum, decay)
print("done")
print()
print("evaluating model...")
print("training accuracy: %f", accuracy_model(m, train))
print("test accuracy: %f", accuracy_model(m, test))loading data...
done
training model...
000000: Loss: 2.370572
000001: Loss: 2.302090
000002: Loss: 2.287877
...
...
...
000997: Loss: 0.347353
000998: Loss: 0.387637
000999: Loss: 0.330449
done
evaluating model...
training accuracy: %f 0.90235
test accuracy: %f 0.9077