def predict(self, image: Picture, path=None):
image_one_channel = image.one_channel().to_float()
heatmap, mask = self._engine.detect(image_one_channel)
plt.imshow(mask)
if path:
plt.savefig(path)
plt.close()
else:
return plt
def attack(self, image_to_attack: Picture, *args, **kwargs):
"""
Perform step of the attack executing the following steps:
(1) -> prepare the image to be used by noiseprint
(2) -> compute the gradient
(3) -> normalize the gradient
(4) -> apply the gradient to the image with the desired strength
(5) -> return the image
:return: attacked image
"""
# compute the attacked image using the original image and the compulative noise to reduce
# rounding artifacts caused by translating the noise from one to 3 channels and vice versa multiple times
image_one_channel = Picture(
(image_to_attack.one_channel() - self.noise).clip(0, 255))
return super(BaseNoiseprintAttack,
self).attack(image_one_channel, args, kwargs)
def prediction_pipeline(self,
image: Picture,
path=None,
original_picture=None,
note="",
omask=None,
debug=False,
adversarial_noise=None):
if image.max() > 1:
image = image.to_float()
image_one_channel = image
if len(image_one_channel.shape
) > 2 and image_one_channel.shape[2] == 3:
image_one_channel = image.one_channel()
if original_picture is not None:
original_picture = prepare_image_noiseprint(original_picture)
n_cols = 4
if original_picture is not None:
n_cols += 1
else:
debug = False
if debug:
fig, axs = plt.subplots(2, n_cols, figsize=(n_cols * 5, 5))
axs0, axs1 = axs[0], axs[1]
else:
fig, axs0 = plt.subplots(1, n_cols, figsize=(n_cols * 5, 5))
noiseprint = self.get_noiseprint(image_one_channel)
heatmap = self._engine.detect(image_one_channel)
#this is the first computation, compute the best f1 threshold initially
axs0[0].imshow(image)
axs0[0].set_title('Image')
axs0[1].imshow(normalize_noiseprint(noiseprint),
clim=[0, 1],
cmap='gray')
axs0[1].set_title('Noiseprint')
axs0[2].imshow(heatmap,
clim=[np.nanmin(heatmap),
np.nanmax(heatmap)],
cmap='jet')
axs0[2].set_title('Heatmap')
if omask is not None:
threshold = find_best_theshold(heatmap, omask)
mask = np.array(heatmap > threshold, int).clip(0, 1)
axs0[3].imshow(mask, clim=[0, 1], cmap='gray')
axs0[3].set_title('Mask')
# remove the x and y ticks
for ax in axs0:
ax.set_xticks([])
ax.set_yticks([])
if original_picture is not None:
noise = self.compute_difference(original_picture.one_channel(),
image_one_channel)
axs0[4].imshow(noise, clim=[0, 1], cmap='gray')
axs0[4].set_title('Difference')
if debug:
original_noiseprint = self._engine.predict(
original_picture.one_channel())
axs1[0].imshow(original_picture)
axs1[0].set_title('Original Image')
axs1[1].imshow(normalize_noiseprint(original_noiseprint),
clim=[0, 1],
cmap='gray')
axs1[1].set_title('Original Noiseprint')
axs1[2].imshow(omask, clim=[0, 1], cmap='gray')
axs1[2].set_title('Original Mask')
noise = self.compute_difference(noiseprint,
original_noiseprint,
enhance_factor=100)
axs1[3].imshow(noise, cmap='gray')
axs1[3].set_title('Noiseprint differences')
axs1[4].imshow(np.where(np.abs(adversarial_noise) > 0, 1, 0),
clim=[0, 1],
cmap='gray')
axs1[4].set_title('Gradient')
# remove the x and y ticks
for ax in axs1:
ax.set_xticks([])
ax.set_yticks([])
if note:
fig.text(0.9,
0.2,
note,
size=14,
horizontalalignment='right',
verticalalignment='top')
if path:
plt.savefig(path, bbox_inches='tight')
plt.close()
else:
return plt
