def morph_image(
src_img,
src_points,
dest_img,
dest_points,
percent,
width=500,
height=600,
):
"""
모핑 이미지로 변환
:param src_img: ndarray source image
:param src_points: source image array of x,y face points
:param dest_img: ndarray destination image
:param dest_points: destination image array of x,y face points
:param percent: 변환 percent
"""
size = (height, width)
points = locator.weighted_average_points(src_points, dest_points, percent)
src_face = warper.warp_image(src_img, src_points, points, size)
end_face = warper.warp_image(dest_img, dest_points, points, size)
average_face = blender.weighted_average(src_face, end_face, percent)
average_face = alpha_image(average_face, points)
return average_face
def morph(src_img,
src_points,
dest_img,
dest_points,
video,
width=500,
height=600,
num_frames=20,
fps=10,
out_frames=None,
out_video=None,
alpha=False,
plot=False,
keep_bg=False):
"""
Create a morph sequence from source to destination image
:param src_img: ndarray source image
:param src_img: source image array of x,y face points
:param dest_img: ndarray destination image
:param dest_img: destination image array of x,y face points
:param video: facemorpher.videoer.Video object
"""
size = (height, width)
stall_frames = np.clip(int(fps * 0.15), 1, fps) # Show first & last longer
plt = plotter.Plotter(plot, num_images=num_frames, out_folder=out_frames)
num_frames -= (stall_frames * 2) # No need to process src and dest image
plt.plot_one(src_img)
video.write(src_img, 1)
# Produce morph frames!
for percent in np.linspace(1, 0, num=num_frames):
points = locator.weighted_average_points(src_points, dest_points,
percent)
src_face = warper.warp_image(src_img, src_points, points, size)
end_face = warper.warp_image(dest_img, dest_points, points, size)
average_face = blender.weighted_average(src_face, end_face, percent)
average_face = alpha_image(average_face,
points) if alpha else average_face
# Average background (find transparent pixel, remove alpha from face image, and than replace transparent with averaged bg)
if (keep_bg):
average_background = blender.weighted_average(
src_img, dest_img, percent)
average_face = alpha_image(average_face, points)
transparent_pixel = average_face[..., 3] == 0
average_face = average_face[..., :3]
average_face[transparent_pixel] = average_background[
transparent_pixel]
plt.plot_one(average_face)
plt.save(average_face)
video.write(average_face)
plt.plot_one(dest_img)
video.write(dest_img, stall_frames)
plt.show()
def morph(src_img,
src_points,
dest_img,
dest_points,
video,
width=500,
height=600,
num_frames=20,
fps=10,
out_frames=None,
out_video=None,
plot=False,
background='black'):
"""
Create a morph sequence from source to destination image
:param src_img: ndarray source image
:param src_points: source image array of x,y face points
:param dest_img: ndarray destination image
:param dest_points: destination image array of x,y face points
:param video: facemorpher.videoer.Video object
"""
size = (height, width)
stall_frames = np.clip(int(fps * 0.15), 1, fps) # Show first & last longer
plt = plotter.Plotter(plot, num_images=num_frames, out_folder=out_frames)
num_frames -= (stall_frames * 2) # No need to process src and dest image
plt.plot_one(src_img)
video.write(src_img, 1)
# Produce morph frames!
for percent in np.linspace(1, 0, num=num_frames):
points = locator.weighted_average_points(src_points, dest_points,
percent)
src_face = warper.warp_image(src_img, src_points, points, size)
end_face = warper.warp_image(dest_img, dest_points, points, size)
average_face = blender.weighted_average(src_face, end_face, percent)
if background in ('transparent', 'average'):
mask = blender.mask_from_points(average_face.shape[:2], points)
average_face = np.dstack((average_face, mask))
if background == 'average':
average_background = blender.weighted_average(
src_img, dest_img, percent)
average_face = blender.overlay_image(average_face, mask,
average_background)
plt.plot_one(average_face)
plt.save(average_face)
video.write(average_face)
plt.plot_one(dest_img)
video.write(dest_img, stall_frames)
plt.show()
def morph_one(src_img,
src_points,
dest_img,
dest_points,
percent,
width=500,
height=600):
size = (height, width)
points = locator.weighted_average_points(src_points, dest_points, percent)
src_face = warper.warp_image(src_img, src_points, points, size)
end_face = warper.warp_image(dest_img, dest_points, points, size)
average_face = blender.weighted_average(src_face, end_face, percent)
return average_face, points
def morph(src_img,
src_points,
dest_img,
dest_points,
video,
width=500,
height=600,
num_frames=20,
fps=10,
out_frames=None,
out_video=None,
alpha=False,
plot=False):
"""
Create a morph sequence from source to destination image
:param out_video:
:param src_img: ndarray source image
:param src_img: source image array of x,y face points
:param dest_img: ndarray destination image
:param dest_img: destination image array of x,y face points
:param video: facemorpher.videoer.Video object
"""
size = (height, width)
stall_frames = np.clip(int(fps * 0.15), 1, fps) # Show first & last longer
plt = plotter.Plotter(plot, num_images=num_frames, out_folder=out_frames)
num_frames -= (stall_frames * 2) # No need to process src and dest image
plt.plot_one(src_img)
video.write(src_img, 1)
# Produce morph frames!
for percent in np.linspace(1, 0, num=num_frames):
points = locator.weighted_average_points(src_points, dest_points,
percent)
src_face = warper.warp_image(src_img, src_points, points, size)
end_face = warper.warp_image(dest_img, dest_points, points, size)
average_face = blender.weighted_average(src_face, end_face, percent)
average_face = alpha_image(average_face,
points) if alpha else average_face
average_bg = blender.weighted_average(src_img, dest_img, percent)
img_over_bg(average_face, average_bg)
plt.plot_one(average_bg, 'save')
video.write(average_bg)
plt.plot_one(dest_img)
video.write(dest_img, stall_frames)
plt.show()
def averager(imgpaths,
dest_filename=None,
width=500,
height=600,
background='black',
blur_edges=False,
out_filename='result.png',
plot=False):
size = (height, width)
images = []
point_set = []
for path in imgpaths:
img, points = load_image_points(path, size)
if img is not None:
images.append(img)
point_set.append(points)
if len(images) == 0:
raise FileNotFoundError('Could not find any valid images.' +
' Supported formats are .jpg, .png, .jpeg')
if dest_filename is not None:
dest_img, dest_points = load_image_points(dest_filename, size)
if dest_img is None or dest_points is None:
raise Exception('No face or detected face points in dest img: ' +
dest_filename)
else:
dest_img = np.zeros(images[0].shape, np.uint8)
dest_points = locator.average_points(point_set)
num_images = len(images)
result_images = np.zeros(images[0].shape, np.float32)
for i in range(num_images):
result_images += warper.warp_image(images[i], point_set[i],
dest_points, size, np.float32)
result_image = np.uint8(result_images / num_images)
face_indexes = np.nonzero(result_image)
dest_img[face_indexes] = result_image[face_indexes]
mask = blender.mask_from_points(size, dest_points)
if blur_edges:
blur_radius = 10
mask = cv2.blur(mask, (blur_radius, blur_radius))
if background in ('transparent', 'average'):
dest_img = np.dstack((dest_img, mask))
if background == 'average':
average_background = locator.average_points(images)
dest_img = blender.overlay_image(dest_img, mask,
average_background)
print('Averaged {} images'.format(num_images))
plt = plotter.Plotter(plot, num_images=1, out_filename=out_filename)
plt.save(dest_img)
plt.plot_one(dest_img)
plt.show()
def averager(imgpaths,
dest_filename=None,
width=500,
height=600,
alpha=False,
blur_edges=False,
out_filename='result.png',
plot=False):
size = (height, width)
images = []
point_set = []
for path in imgpaths:
img, points = load_image_points(path, size)
if img is not None:
images.append(img)
point_set.append(points)
if len(images) == 0:
raise FileNotFoundError('Could not find any valid images.' +
' Supported formats are .jpg, .png, .jpeg')
if dest_filename is not None:
dest_img, dest_points = load_image_points(dest_filename, size)
if dest_img is None or dest_points is None:
raise Exception('No face or detected face points in dest img: ' +
dest_filename)
else:
dest_img = np.zeros(images[0].shape, np.uint8)
dest_points = locator.average_points(point_set)
num_images = len(images)
result_images = np.zeros(images[0].shape, np.float32)
for i in range(num_images):
result_images += warper.warp_image(images[i], point_set[i],
dest_points, size, np.float32)
result_image = np.uint8(result_images / num_images)
face_indexes = np.nonzero(result_image)
dest_img[face_indexes] = result_image[face_indexes]
mask = blender.mask_from_points(size, dest_points)
if blur_edges:
blur_radius = 10
mask = cv2.blur(mask, (blur_radius, blur_radius))
if alpha:
dest_img = np.dstack((dest_img, mask))
mpimg.imsave(out_filename, dest_img)
if plot:
plt.axis('off')
plt.imshow(dest_img)
plt.show()
def average_face(imgpaths,
width=500,
height=500,
background='black',
blur_edges=False,
out_filename='result.jpg'):
size = (height, width)
images = []
point_set = []
for path in imgpaths:
img, points = load_image_points(path, size)
if img is not None:
images.append(img)
point_set.append(points)
if len(images) == 0:
raise FileNotFoundError(
'Could not find any valid images. Supported formats are .jpg, .png, .jpeg'
)
dest_img, dest_points = load_image_points(REFERENCE_IMG_PATH, size)
num_images = len(images)
result_images = np.zeros(images[0].shape, np.float32)
for i in range(num_images):
result_images += warper.warp_image(images[i], point_set[i],
dest_points, size, np.float32)
result_image = np.uint8(result_images / num_images)
face_indexes = np.nonzero(result_image)
dest_img[face_indexes] = result_image[face_indexes]
mask = blender.mask_from_points(size, dest_points)
if blur_edges:
blur_radius = 10
mask = cv2.blur(mask, (blur_radius, blur_radius))
if background in ('transparent', 'average'):
dest_img = np.dstack((dest_img, mask))
if background == 'average':
# average_background = np.uint8(locator.average_points(images))
avg_background = perlin_background(images)
avg_background[np.where(
(avg_background == [0, 0, 0]).all(axis=2))] = [
128, 128, 128
] # black -> gray pixels in background
dest_img = blender.overlay_image(dest_img, mask, avg_background)
print('Averaged {} images'.format(num_images))
plt = plotter.Plotter(False, num_images=1, out_filename=out_filename)
plt.save(dest_img)
def alignment(content, style):
content_img = np.array(Image.from_file(content).data)
style_img = np.array(Image.from_file(style).data)
content_name = os.path.splitext(content)[0]
style_name = os.path.splitext(style)[0]
# extraction of facial landmarks
content_pts = locator.face_points(content_img, add_boundary_points=True)
style_pts = locator.face_points(style_img, add_boundary_points=True)
# translation in terms of coordinates
content_coords = warper.grid_coordinates(content_pts)
style_coords = warper.grid_coordinates(style_pts)
# warp the face from the style image, given the extracted landmarks
style_aligned_img = warper.warp_image(style_img, style_pts, content_pts, \
content_img.shape)
PIL.Image.fromarray(style_aligned_img).save(style_name+"_aligned.png")
# apply the warped face from the style image on the content image
mask = np.ma.masked_greater(style_aligned_img, 0)
content_img[(mask!=0)] = 0
content_aligned_img = style_aligned_img + content_img
PIL.Image.fromarray(content_aligned_img).save(content_name+"_aligned.png")
# obtain a delaunay triangulation of the style image's facial landmarks
delaunay_style = spatial.Delaunay(style_pts)
# visualize the delaunay triangulation of the style image's facial landmarks
plt.triplot(style_pts[:,0], style_pts[:,1], delaunay_style.simplices.copy())
plt.imshow(style_img)
plt.plot(style_pts[:,0], style_pts[:,1], 'o')
plt.savefig(style_name+"_delaunay.png")
# apply the same triangulation to the new image, warped to fit the content
# and visualize it
plt.figure()
plt.triplot(content_pts[:,0], content_pts[:,1], delaunay_style.simplices.copy())
plt.imshow(content_aligned_img)
plt.plot(content_pts[:,0], content_pts[:,1], 'o')
plt.savefig(content_name+"_aligned_delaunay.png")
def morph(src_img,
src_points,
dest_img,
dest_points,
video,
width=500,
height=600,
num_frames=20,
fps=10,
out_frames=None,
out_video=None,
alpha=False,
plot=False):
"""
Create a morph sequence from source to destination image
:param src_img: ndarray source image
:param src_img: source image array of x,y face points
:param dest_img: ndarray destination image
:param dest_img: destination image array of x,y face points
:param video: facemorpher.videoer.Video object
"""
size = (height, width)
stall_frames = np.clip(int(fps * 0.15), 1, fps) # Show first & last longer
plt = plotter.Plotter(plot, num_images=num_frames, out_folder=out_frames)
num_frames -= (stall_frames * 2) # No need to process src and dest image
label = plotter.Plotter(plot,
num_images=2,
out_folder=out_frames,
label=True)
label.plot_one(src_img, src_points)
label.plot_one(dest_img, dest_points)
label.show()
plt.plot_one(src_img)
video.write(src_img, 1)
try:
os.mkdir(os.path.join(os.getcwd(), 'result'))
os.mkdir(os.path.join(os.getcwd(), 'result', 'src'))
os.mkdir(os.path.join(os.getcwd(), 'result', 'src_corners'))
os.mkdir(os.path.join(os.getcwd(), 'result', 'end'))
os.mkdir(os.path.join(os.getcwd(), 'result', 'average'))
except Exception as e:
print(e)
# Produce morph frames!
for percent in np.linspace(1, 0, num=num_frames):
points = locator.weighted_average_points(src_points, dest_points,
percent)
src_face = warper.warp_image(src_img, src_points, points, size)
end_face = warper.warp_image(dest_img, dest_points, points, size)
average_face = blender.weighted_average(src_face, end_face, percent)
average_face = alpha_image(average_face,
points) if alpha else average_face
average_face[:, :, :3] = correct_colours(src_face, average_face,
np.matrix(points))
corners = np.array([
np.array([0, 0]),
np.array([0, height - 2]),
np.array([width - 2, 0]),
np.array([width - 2, height - 2])
])
src_points_with_corners = np.concatenate((src_points, corners))
points_with_corners = np.concatenate((points, corners))
src_face_corners = warper.warp_image(src_img, src_points_with_corners,
points_with_corners, size)
average_face = process_edge(src_face_corners, average_face, width,
height)
plt.plot_one(average_face)
filename = '%d.jpg' % int((1 - percent) * num_frames)
cv2.imwrite(os.path.join(os.getcwd(), 'result', 'src', filename),
src_face)
cv2.imwrite(
os.path.join(os.getcwd(), 'result', 'src_corners', filename),
src_face_corners)
cv2.imwrite(os.path.join(os.getcwd(), 'result', 'end', filename),
end_face)
cv2.imwrite(os.path.join(os.getcwd(), 'result', 'average', filename),
average_face)
plt.save(average_face)
video.write(average_face)
plt.plot_one(dest_img)
video.write(dest_img, stall_frames)
plt.show()
