def create_shape_image_sample(shape, sample_width=256, sample_height=256):
""" Return a centered image sample of the shape, or None if a centered
box intersects the shape edge """
from shapes.models import ShapeImageSample
from common.wavelets import compute_wavelet_feature_vector
if ShapeImageSample.objects.filter(shape=shape).exists():
return
image = open_image(shape.photo.image_2048)
image_width, image_height = image.size
triangles = parse_triangles(shape.triangles)
vertices = [(x * image_width, y * image_height)
for (x, y) in parse_vertices(shape.vertices)]
b = bbox_vertices(vertices)
# make sure box is big enough
if b[2] - b[0] < sample_width or b[3] - b[1] < sample_height:
return None
# try random boxes
filled = False
for iters in xrange(1000):
x = int(random.uniform(b[0] + sample_width / 2, b[2] - sample_width / 2))
y = int(random.uniform(b[1] + sample_height / 2, b[3] - sample_height / 2))
box = (x - sample_width / 2, y - sample_height / 2,
x + sample_width / 2, y + sample_height / 2)
box = [int(f) for f in box]
# make sure box is filled entirely
poly = Image.new(mode='1', size=(box[2] - box[0], box[3] - box[1]), color=0)
draw = ImageDraw.Draw(poly)
vertices_shifted = [(x - box[0], y - box[1]) for (x, y) in vertices]
for tri in triangles:
points = [vertices_shifted[tri[t]] for t in (0, 1, 2)]
draw.polygon(points, fill=1)
del draw
filled = True
for p in poly.getdata():
if p != 1:
filled = False
break
if filled:
break
if not filled:
return None
# create sample
sample, created = ShapeImageSample.objects.get_or_create(
shape=shape, defaults={'bbox': json.dumps(box)})
if created:
sample_image = image.crop(box)
sample.feature_vector = \
compute_wavelet_feature_vector(sample_image)
save_obj_attr_image(
sample, attr='image', img=sample_image, format='jpg', save=True)
return sample
def save(self, *args, **kwargs):
if not self.id:
self.orthogonalize(save=False)
if not self.image_rectified:
from normals.utils import rectify_shape_from_uvnb
img = rectify_shape_from_uvnb(self.shape, self)
save_obj_attr_image(
self, attr='image_rectified', img=img, save=False)
super(ShapeRectifiedNormalLabel, self).save(*args, **kwargs)
def fill_in_bbox_task(shape):
""" Helper to fill in the potentially empty image_bbox field """
image_bbox = mask_complex_polygon(
image=open_image(shape.photo.image_orig),
vertices=shape.vertices,
triangles=shape.triangles,
bbox_only=True)
save_obj_attr_image(shape, attr='image_bbox',
img=image_bbox,
format='jpg', save=True)
def save(self, *args, **kwargs):
if not self.id:
self.orthogonalize(save=False)
if not self.image_rectified:
from normals.utils import rectify_shape_from_uvnb
img = rectify_shape_from_uvnb(self.shape, self)
save_obj_attr_image(self,
attr='image_rectified',
img=img,
save=False)
super(ShapeRectifiedNormalLabel, self).save(*args, **kwargs)
def fill_in_bbox_task(shape):
""" Helper to fill in the potentially empty image_bbox field """
image_bbox = mask_complex_polygon(image=open_image(shape.photo.image_orig),
vertices=shape.vertices,
triangles=shape.triangles,
bbox_only=True)
save_obj_attr_image(shape,
attr='image_bbox',
img=image_bbox,
format='jpg',
save=True)
def update_shape_image_crop(shape, save=True):
""" Update the cropped image for a shape """
# compute masked image
image_crop, image_bbox = mask_complex_polygon(
image=open_image(shape.photo.image_orig),
vertices=shape.vertices,
triangles=shape.triangles)
if image_crop:
save_obj_attr_image(shape, attr='image_crop', img=image_crop, format='png', save=save)
shape.image_square_300.generate()
if image_bbox:
save_obj_attr_image(shape, attr='image_bbox', img=image_bbox, format='jpg', save=save)
shape.image_bbox_1024.generate()
def update_shape_image_pbox(shape, padding=0.25, save=True):
""" Update the pbox image for a shape """
# load image
photo = shape.photo.__class__.objects.get(id=shape.photo.id)
image = open_image(photo.image_orig)
w, h = image.size
# compute bbox
vertices = [(v[0] * w, v[1] * h) for v in parse_vertices(shape.vertices)]
bbox = bbox_vertices(vertices)
if (len(vertices) < 3 or bbox[0] >= bbox[2] or bbox[1] >= bbox[3]):
return None
# compute pbox
padding_x = (bbox[2] - bbox[0]) * padding
padding_y = (bbox[3] - bbox[1]) * padding
pbox = [
max(0, bbox[0] - padding_x),
max(0, bbox[1] - padding_y),
min(w, bbox[2] + padding_x),
min(h, bbox[3] + padding_y),
]
# make square
if pbox[3] - pbox[1] > pbox[2] - pbox[0]:
mid_x = 0.5 * (pbox[2] + pbox[0])
half_h = 0.5 * (pbox[3] - pbox[1])
pbox[0] = mid_x - half_h
pbox[2] = mid_x + half_h
if pbox[0] < 0:
pbox[2] = min(w, pbox[2] - pbox[0])
pbox[0] = 0
elif pbox[2] > w:
pbox[0] = max(0, pbox[0] - (pbox[2] - w))
pbox[2] = w
else:
mid_y = 0.5 * (pbox[3] + pbox[1])
half_w = 0.5 * (pbox[2] - pbox[0])
pbox[1] = mid_y - half_w
pbox[3] = mid_y + half_w
if pbox[1] < 0:
pbox[3] = min(h, pbox[3] - pbox[1])
pbox[1] = 0
elif pbox[3] > h:
pbox[1] = max(0, pbox[1] - (pbox[3] - h))
pbox[3] = h
# crop image
image_pbox = image.crop([int(v) for v in pbox])
if image_pbox:
shape.pbox = json.dumps([
float(pbox[0]) / w,
float(pbox[1]) / h,
float(pbox[2]) / w,
float(pbox[3]) / h,
])
# pbox is in units of pixels, so this gives the pixel ratio
shape.pbox_aspect_ratio = float(pbox[2] - pbox[0]) / float(pbox[3] - pbox[1])
#print 'bbox: %s, pbox: %s' % (bbox, pbox)
save_obj_attr_image(shape, attr='image_pbox',
img=image_pbox, format='jpg', save=save)
shape.image_pbox_300.generate()
shape.image_pbox_512.generate()
def update_shape_image_pbox(shape, padding=0.25, save=True):
""" Update the pbox image for a shape """
# load image
image = open_image(shape.photo.image_orig)
w, h = image.size
# compute bbox
vertices = [(v[0] * w, v[1] * h) for v in parse_vertices(shape.vertices)]
bbox = bbox_vertices(vertices)
if (len(vertices) < 3 or bbox[0] >= bbox[2] or bbox[1] >= bbox[3]):
return None
# compute pbox
padding_x = (bbox[2] - bbox[0]) * padding
padding_y = (bbox[3] - bbox[1]) * padding
pbox = [
max(0, bbox[0] - padding_x),
max(0, bbox[1] - padding_y),
min(w, bbox[2] + padding_x),
min(h, bbox[3] + padding_y),
]
# make square
if pbox[3] - pbox[1] > pbox[2] - pbox[0]:
mid_x = 0.5 * (pbox[2] + pbox[0])
half_h = 0.5 * (pbox[3] - pbox[1])
pbox[0] = mid_x - half_h
pbox[2] = mid_x + half_h
if pbox[0] < 0:
pbox[2] = min(w, pbox[2] - pbox[0])
pbox[0] = 0
elif pbox[2] > w:
pbox[0] = max(0, pbox[0] - (pbox[2] - w))
pbox[2] = w
else:
mid_y = 0.5 * (pbox[3] + pbox[1])
half_w = 0.5 * (pbox[2] - pbox[0])
pbox[1] = mid_y - half_w
pbox[3] = mid_y + half_w
if pbox[1] < 0:
pbox[3] = min(h, pbox[3] - pbox[1])
pbox[1] = 0
elif pbox[3] > h:
pbox[1] = max(0, pbox[1] - (pbox[3] - h))
pbox[3] = h
# crop image
image_pbox = image.crop([int(v) for v in pbox])
if image_pbox:
shape.pbox = json.dumps([
float(pbox[0]) / w,
float(pbox[1]) / h,
float(pbox[2]) / w,
float(pbox[3]) / h,
])
# pbox is in units of pixels, so this gives the pixel ratio
shape.pbox_aspect_ratio = float(pbox[2] - pbox[0]) / float(pbox[3] - pbox[1])
#print 'bbox: %s, pbox: %s' % (bbox, pbox)
save_obj_attr_image(shape, attr='image_pbox',
img=image_pbox, format='jpg', save=save)
shape.image_pbox_300.generate()
shape.image_pbox_512.generate()
def intrinsic_decomposition_task(photo_id, algorithm_id, task_version=0):
"""
Decompose an image with a given algorithm and set of parameters. The image
is resized to fit in a 512 by 512 box. The resize operation happens in the
file's storage colorspace (likely sRGB).
:param photo_id: ``photo.id``
:param algorithm_id: ``algorithm.id``
"""
#algorithm, _ = IntrinsicImagesAlgorithm.objects.get_or_create(
#slug=algorithm_slug, parameters=json.dumps(parameters, sort_keys=True),
#baseline=algorithm_slug.startswith('baseline_'))
algorithm = IntrinsicImagesAlgorithm.objects.get(id=algorithm_id)
parameters = json.loads(algorithm.parameters)
if task_version != algorithm.task_version:
print "Version changed (%s --> %s): exiting" % (task_version,
algorithm.task_version)
return
elif not algorithm.active:
print "Algorithm not active: %s %s: exiting" % (algorithm.slug,
algorithm.parameters)
return
elif IntrinsicImagesDecomposition.objects.filter(
photo_id=photo_id, algorithm=algorithm).exists():
print "Already decomposed: photo_id: %s, algorithm: %s %s: exiting" % (
photo_id, algorithm.slug, algorithm.parameters)
return
print 'intrinsic_decomposition_task: photo_id: %s, slug: %s, parameters: %s' % (
photo_id, algorithm.slug, parameters)
# download image
photo = Photo.objects.get(id=photo_id)
image = ResizeToFit(512, 512).process(photo.open_image(width='orig'))
# decompose
import intrinsic.algorithm
func = getattr(intrinsic.algorithm, algorithm.slug)
r, s, runtime = func(image, **parameters)
r = numpy_to_pil(r)
s = numpy_to_pil(s)
# save: use atomic so that if the image save fails, the record is not kept
with transaction.atomic():
decomposition, _ = IntrinsicImagesDecomposition.objects \
.get_or_create(photo_id=photo_id, algorithm=algorithm)
decomposition.runtime = runtime
save_obj_attr_image(decomposition,
attr='reflectance_image',
img=r,
format='png',
save=False)
save_obj_attr_image(decomposition,
attr='shading_image',
img=s,
format='png',
save=False)
from intrinsic.evaluation import evaluate_error
update_kwargs = evaluate_error(photo_id, r)
for k, v in update_kwargs.iteritems():
setattr(decomposition, k, v)
decomposition.save()
def _run_algorithm(photo, function, slug, parameters={},
image_size=512, baseline=False):
""" Sets up an algorithm in the database, calls ``function``, then stores
the result in the database """
if not isinstance(photo, Photo):
time_start = timeit.default_timer()
r, s = function(image=photo, **parameters)
time_end = timeit.default_timer()
runtime = time_end - time_start
r, s = [process_layer(x) for x in (r, s)]
return r, s, runtime
# ensure a consistent order for parameters
algorithm, _ = IntrinsicImagesAlgorithm.objects.get_or_create(
slug=slug, parameters=json.dumps(parameters, sort_keys=True), baseline=baseline)
if IntrinsicImagesDecomposition.objects.filter(
photo=photo, algorithm=algorithm).exists():
print '_run_algorithm: EXISTS: photo %s, algorithm %s, params %s' % (
photo.id, slug, parameters)
return
else:
print '_run_algorithm: starting: photo %s, algorithm %s, params %s' % (
photo.id, slug, parameters)
# load and resize image (do it here rather than load the pre-resized photo
# thumbnail to avoid jpg artifacts)
attr = '_intrinsic_algorithm_photo_%s' % image_size
if hasattr(photo, attr):
image = getattr(photo, attr)
else:
image = photo.open_image(width='orig')
image = ResizeToFit(image_size, image_size).process(image)
setattr(photo, attr, image)
time_start = timeit.default_timer()
# r, s: linar numpy arrays
r, s = function(image=image, **parameters)
time_end = timeit.default_timer()
runtime = time_end - time_start
# r, s: sRGB numpy arrays
r, s = [process_layer(x) for x in (r, s)]
# r, s: sRGB PIL images
reflectance_image = numpy_to_pil(r)
shading_image = numpy_to_pil(s)
# save in database
with transaction.atomic():
decomposition, _ = IntrinsicImagesDecomposition.objects \
.get_or_create(photo=photo, algorithm=algorithm)
# fill in fields
decomposition.runtime = runtime
save_obj_attr_image(
decomposition, attr='reflectance_image',
img=reflectance_image, format='png', save=False)
save_obj_attr_image(
decomposition, attr='shading_image',
img=shading_image, format='png', save=False)
# comupte error
from intrinsic.evaluation import evaluate_error
update_kwargs = evaluate_error(photo.id, reflectance_image)
for k, v in update_kwargs.iteritems():
setattr(decomposition, k, v)
# save to database
decomposition.save()
print '_run_algorithm: DONE: photo %s, algorithm %s, params %s, runtime: %s' % (
photo.id, slug, parameters, runtime)
return r, s, runtime
def _run_algorithm(photo,
function,
slug,
parameters={},
image_size=512,
baseline=False):
""" Sets up an algorithm in the database, calls ``function``, then stores
the result in the database """
if not isinstance(photo, Photo):
time_start = timeit.default_timer()
r, s = function(image=photo, **parameters)
time_end = timeit.default_timer()
runtime = time_end - time_start
r, s = [process_layer(x) for x in (r, s)]
return r, s, runtime
# ensure a consistent order for parameters
algorithm, _ = IntrinsicImagesAlgorithm.objects.get_or_create(
slug=slug,
parameters=json.dumps(parameters, sort_keys=True),
baseline=baseline)
if IntrinsicImagesDecomposition.objects.filter(
photo=photo, algorithm=algorithm).exists():
print '_run_algorithm: EXISTS: photo %s, algorithm %s, params %s' % (
photo.id, slug, parameters)
return
else:
print '_run_algorithm: starting: photo %s, algorithm %s, params %s' % (
photo.id, slug, parameters)
# load and resize image (do it here rather than load the pre-resized photo
# thumbnail to avoid jpg artifacts)
attr = '_intrinsic_algorithm_photo_%s' % image_size
if hasattr(photo, attr):
image = getattr(photo, attr)
else:
image = photo.open_image(width='orig')
image = ResizeToFit(image_size, image_size).process(image)
setattr(photo, attr, image)
time_start = timeit.default_timer()
# r, s: linar numpy arrays
r, s = function(image=image, **parameters)
time_end = timeit.default_timer()
runtime = time_end - time_start
# r, s: sRGB numpy arrays
r, s = [process_layer(x) for x in (r, s)]
# r, s: sRGB PIL images
reflectance_image = numpy_to_pil(r)
shading_image = numpy_to_pil(s)
# save in database
with transaction.atomic():
decomposition, _ = IntrinsicImagesDecomposition.objects \
.get_or_create(photo=photo, algorithm=algorithm)
# fill in fields
decomposition.runtime = runtime
save_obj_attr_image(decomposition,
attr='reflectance_image',
img=reflectance_image,
format='png',
save=False)
save_obj_attr_image(decomposition,
attr='shading_image',
img=shading_image,
format='png',
save=False)
# comupte error
from intrinsic.evaluation import evaluate_error
update_kwargs = evaluate_error(photo.id, reflectance_image)
for k, v in update_kwargs.iteritems():
setattr(decomposition, k, v)
# save to database
decomposition.save()
print '_run_algorithm: DONE: photo %s, algorithm %s, params %s, runtime: %s' % (
photo.id, slug, parameters, runtime)
return r, s, runtime
