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- # main imports
- import numpy as np
- import sys
- # image transform imports
- from PIL import Image
- from skimage import color
- from sklearn.decomposition import FastICA
- from sklearn.decomposition import IncrementalPCA
- from sklearn.decomposition import TruncatedSVD
- from numpy.linalg import svd as lin_svd
- from scipy.signal import medfilt2d, wiener, cwt
- import pywt
- import cv2
- from ipfml.processing import transform, compression, segmentation
- from ipfml.filters import convolution, kernels
- from ipfml import utils
- # modules and config imports
- sys.path.insert(0, '') # trick to enable import of main folder module
- import custom_config as cfg
- from modules.utils import data as dt
- def get_image_features(data_type, block):
- """
- Method which returns the data type expected
- """
- if data_type == 'lab':
- block_file_path = '/tmp/lab_img.png'
- block.save(block_file_path)
- data = transform.get_LAB_L_SVD_s(Image.open(block_file_path))
- if data_type == 'mscn':
- img_mscn_revisited = transform.rgb_to_mscn(block)
- # save tmp as img
- img_output = Image.fromarray(img_mscn_revisited.astype('uint8'), 'L')
- mscn_revisited_file_path = '/tmp/mscn_revisited_img.png'
- img_output.save(mscn_revisited_file_path)
- img_block = Image.open(mscn_revisited_file_path)
- # extract from temp image
- data = compression.get_SVD_s(img_block)
- """if data_type == 'mscn':
- img_gray = np.array(color.rgb2gray(np.asarray(block))*255, 'uint8')
- img_mscn = transform.calculate_mscn_coefficients(img_gray, 7)
- img_mscn_norm = transform.normalize_2D_arr(img_mscn)
- img_mscn_gray = np.array(img_mscn_norm*255, 'uint8')
- data = compression.get_SVD_s(img_mscn_gray)
- """
- if data_type == 'low_bits_6':
- low_bits_6 = transform.rgb_to_LAB_L_low_bits(block, 6)
- data = compression.get_SVD_s(low_bits_6)
- if data_type == 'low_bits_5':
- low_bits_5 = transform.rgb_to_LAB_L_low_bits(block, 5)
- data = compression.get_SVD_s(low_bits_5)
- if data_type == 'low_bits_4':
- low_bits_4 = transform.rgb_to_LAB_L_low_bits(block, 4)
- data = compression.get_SVD_s(low_bits_4)
- if data_type == 'low_bits_3':
- low_bits_3 = transform.rgb_to_LAB_L_low_bits(block, 3)
- data = compression.get_SVD_s(low_bits_3)
- if data_type == 'low_bits_2':
- low_bits_2 = transform.rgb_to_LAB_L_low_bits(block, 2)
- data = compression.get_SVD_s(low_bits_2)
- if data_type == 'low_bits_4_shifted_2':
- data = compression.get_SVD_s(transform.rgb_to_LAB_L_bits(block, (3, 6)))
- if data_type == 'sub_blocks_stats':
- block = np.asarray(block)
- width, height, _= block.shape
- sub_width, sub_height = int(width / 4), int(height / 4)
- sub_blocks = segmentation.divide_in_blocks(block, (sub_width, sub_height))
- data = []
- for sub_b in sub_blocks:
- # by default use the whole lab L canal
- l_svd_data = np.array(transform.get_LAB_L_SVD_s(sub_b))
- # get information we want from svd
- data.append(np.mean(l_svd_data))
- data.append(np.median(l_svd_data))
- data.append(np.percentile(l_svd_data, 25))
- data.append(np.percentile(l_svd_data, 75))
- data.append(np.var(l_svd_data))
- area_under_curve = utils.integral_area_trapz(l_svd_data, dx=100)
- data.append(area_under_curve)
- # convert into numpy array after computing all stats
- data = np.asarray(data)
- if data_type == 'sub_blocks_stats_reduced':
- block = np.asarray(block)
- width, height, _= block.shape
- sub_width, sub_height = int(width / 4), int(height / 4)
- sub_blocks = segmentation.divide_in_blocks(block, (sub_width, sub_height))
- data = []
- for sub_b in sub_blocks:
- # by default use the whole lab L canal
- l_svd_data = np.array(transform.get_LAB_L_SVD_s(sub_b))
- # get information we want from svd
- data.append(np.mean(l_svd_data))
- data.append(np.median(l_svd_data))
- data.append(np.percentile(l_svd_data, 25))
- data.append(np.percentile(l_svd_data, 75))
- data.append(np.var(l_svd_data))
- # convert into numpy array after computing all stats
- data = np.asarray(data)
- if data_type == 'sub_blocks_area':
- block = np.asarray(block)
- width, height, _= block.shape
- sub_width, sub_height = int(width / 8), int(height / 8)
- sub_blocks = segmentation.divide_in_blocks(block, (sub_width, sub_height))
- data = []
- for sub_b in sub_blocks:
- # by default use the whole lab L canal
- l_svd_data = np.array(transform.get_LAB_L_SVD_s(sub_b))
- area_under_curve = utils.integral_area_trapz(l_svd_data, dx=50)
- data.append(area_under_curve)
- # convert into numpy array after computing all stats
- data = np.asarray(data)
- if data_type == 'sub_blocks_area_normed':
- block = np.asarray(block)
- width, height, _= block.shape
- sub_width, sub_height = int(width / 8), int(height / 8)
- sub_blocks = segmentation.divide_in_blocks(block, (sub_width, sub_height))
- data = []
- for sub_b in sub_blocks:
- # by default use the whole lab L canal
- l_svd_data = np.array(transform.get_LAB_L_SVD_s(sub_b))
- l_svd_data = utils.normalize_arr(l_svd_data)
- area_under_curve = utils.integral_area_trapz(l_svd_data, dx=50)
- data.append(area_under_curve)
- # convert into numpy array after computing all stats
- data = np.asarray(data)
- if data_type == 'mscn_var_4':
- data = _get_mscn_variance(block, (100, 100))
- if data_type == 'mscn_var_16':
- data = _get_mscn_variance(block, (50, 50))
- if data_type == 'mscn_var_64':
- data = _get_mscn_variance(block, (25, 25))
- if data_type == 'mscn_var_16_max':
- data = _get_mscn_variance(block, (50, 50))
- data = np.asarray(data)
- size = int(len(data) / 4)
- indices = data.argsort()[-size:][::-1]
- data = data[indices]
- if data_type == 'mscn_var_64_max':
- data = _get_mscn_variance(block, (25, 25))
- data = np.asarray(data)
- size = int(len(data) / 4)
- indices = data.argsort()[-size:][::-1]
- data = data[indices]
- if data_type == 'ica_diff':
- current_image = transform.get_LAB_L(block)
- ica = FastICA(n_components=50)
- ica.fit(current_image)
- image_ica = ica.fit_transform(current_image)
- image_restored = ica.inverse_transform(image_ica)
- final_image = utils.normalize_2D_arr(image_restored)
- final_image = np.array(final_image * 255, 'uint8')
- sv_values = utils.normalize_arr(compression.get_SVD_s(current_image))
- ica_sv_values = utils.normalize_arr(compression.get_SVD_s(final_image))
- data = abs(np.array(sv_values) - np.array(ica_sv_values))
- if data_type == 'svd_trunc_diff':
- current_image = transform.get_LAB_L(block)
- svd = TruncatedSVD(n_components=30, n_iter=100, random_state=42)
- transformed_image = svd.fit_transform(current_image)
- restored_image = svd.inverse_transform(transformed_image)
- reduced_image = (current_image - restored_image)
- U, s, V = compression.get_SVD(reduced_image)
- data = s
- if data_type == 'ipca_diff':
- current_image = transform.get_LAB_L(block)
- transformer = IncrementalPCA(n_components=20, batch_size=25)
- transformed_image = transformer.fit_transform(current_image)
- restored_image = transformer.inverse_transform(transformed_image)
- reduced_image = (current_image - restored_image)
- U, s, V = compression.get_SVD(reduced_image)
- data = s
- if data_type == 'svd_reconstruct':
- reconstructed_interval = (90, 200)
- begin, end = reconstructed_interval
- lab_img = transform.get_LAB_L(block)
- lab_img = np.array(lab_img, 'uint8')
- U, s, V = lin_svd(lab_img, full_matrices=True)
- smat = np.zeros((end-begin, end-begin), dtype=complex)
- smat[:, :] = np.diag(s[begin:end])
- output_img = np.dot(U[:, begin:end], np.dot(smat, V[begin:end, :]))
- output_img = np.array(output_img, 'uint8')
- data = compression.get_SVD_s(output_img)
- if 'sv_std_filters' in data_type:
- # convert into lab by default to apply filters
- lab_img = transform.get_LAB_L(block)
- arr = np.array(lab_img)
- images = []
-
- # Apply list of filter on arr
- images.append(medfilt2d(arr, [3, 3]))
- images.append(medfilt2d(arr, [5, 5]))
- images.append(wiener(arr, [3, 3]))
- images.append(wiener(arr, [5, 5]))
-
- # By default computation of current block image
- s_arr = compression.get_SVD_s(arr)
- sv_vector = [s_arr]
- # for each new image apply SVD and get SV
- for img in images:
- s = compression.get_SVD_s(img)
- sv_vector.append(s)
-
- sv_array = np.array(sv_vector)
-
- _, len = sv_array.shape
-
- sv_std = []
-
- # normalize each SV vectors and compute standard deviation for each sub vectors
- for i in range(len):
- sv_array[:, i] = utils.normalize_arr(sv_array[:, i])
- sv_std.append(np.std(sv_array[:, i]))
-
- indices = []
- if 'lowest' in data_type:
- indices = utils.get_indices_of_lowest_values(sv_std, 200)
- if 'highest' in data_type:
- indices = utils.get_indices_of_highest_values(sv_std, 200)
- # data are arranged following std trend computed
- data = s_arr[indices]
- # with the use of wavelet
- if 'wave_sv_std_filters' in data_type:
- # convert into lab by default to apply filters
- lab_img = transform.get_LAB_L(block)
- arr = np.array(lab_img)
- images = []
-
- # Apply list of filter on arr
- images.append(medfilt2d(arr, [3, 3]))
-
- # By default computation of current block image
- s_arr = compression.get_SVD_s(arr)
- sv_vector = [s_arr]
- # for each new image apply SVD and get SV
- for img in images:
- s = compression.get_SVD_s(img)
- sv_vector.append(s)
-
- sv_array = np.array(sv_vector)
-
- _, len = sv_array.shape
-
- sv_std = []
-
- # normalize each SV vectors and compute standard deviation for each sub vectors
- for i in range(len):
- sv_array[:, i] = utils.normalize_arr(sv_array[:, i])
- sv_std.append(np.std(sv_array[:, i]))
-
- indices = []
- if 'lowest' in data_type:
- indices = utils.get_indices_of_lowest_values(sv_std, 200)
- if 'highest' in data_type:
- indices = utils.get_indices_of_highest_values(sv_std, 200)
- # data are arranged following std trend computed
- data = s_arr[indices]
- # with the use of wavelet
- if 'sv_std_filters_full' in data_type:
- # convert into lab by default to apply filters
- lab_img = transform.get_LAB_L(block)
- arr = np.array(lab_img)
- images = []
-
- # Apply list of filter on arr
- kernel = np.ones((3,3),np.float32)/9
- images.append(cv2.filter2D(arr,-1,kernel))
- kernel = np.ones((5,5),np.float32)/25
- images.append(cv2.filter2D(arr,-1,kernel))
- images.append(cv2.GaussianBlur(arr, (3, 3), 0.5))
- images.append(cv2.GaussianBlur(arr, (3, 3), 1))
- images.append(cv2.GaussianBlur(arr, (3, 3), 1.5))
- images.append(cv2.GaussianBlur(arr, (5, 5), 0.5))
- images.append(cv2.GaussianBlur(arr, (5, 5), 1))
- images.append(cv2.GaussianBlur(arr, (5, 5), 1.5))
- images.append(medfilt2d(arr, [3, 3]))
- images.append(medfilt2d(arr, [5, 5]))
- images.append(wiener(arr, [3, 3]))
- images.append(wiener(arr, [5, 5]))
- wave = w2d(arr, 'db1', 2)
- images.append(np.array(wave, 'float64'))
-
- # By default computation of current block image
- s_arr = compression.get_SVD_s(arr)
- sv_vector = [s_arr]
- # for each new image apply SVD and get SV
- for img in images:
- s = compression.get_SVD_s(img)
- sv_vector.append(s)
-
- sv_array = np.array(sv_vector)
-
- _, length = sv_array.shape
-
- sv_std = []
-
- # normalize each SV vectors and compute standard deviation for each sub vectors
- for i in range(length):
- sv_array[:, i] = utils.normalize_arr(sv_array[:, i])
- sv_std.append(np.std(sv_array[:, i]))
-
- indices = []
- if 'lowest' in data_type:
- indices = utils.get_indices_of_lowest_values(sv_std, 200)
- if 'highest' in data_type:
- indices = utils.get_indices_of_highest_values(sv_std, 200)
- # data are arranged following std trend computed
- data = s_arr[indices]
- if 'sv_entropy_std_filters' in data_type:
- lab_img = transform.get_LAB_L(block)
- arr = np.array(lab_img)
- images = []
- kernel = np.ones((3,3),np.float32)/9
- images.append(cv2.filter2D(arr,-1,kernel))
- kernel = np.ones((5,5),np.float32)/25
- images.append(cv2.filter2D(arr,-1,kernel))
- images.append(cv2.GaussianBlur(arr, (3, 3), 0.5))
- images.append(cv2.GaussianBlur(arr, (3, 3), 1))
- images.append(cv2.GaussianBlur(arr, (3, 3), 1.5))
- images.append(cv2.GaussianBlur(arr, (5, 5), 0.5))
- images.append(cv2.GaussianBlur(arr, (5, 5), 1))
- images.append(cv2.GaussianBlur(arr, (5, 5), 1.5))
- images.append(medfilt2d(arr, [3, 3]))
- images.append(medfilt2d(arr, [5, 5]))
- images.append(wiener(arr, [3, 3]))
- images.append(wiener(arr, [5, 5]))
- wave = w2d(arr, 'db1', 2)
- images.append(np.array(wave, 'float64'))
- sv_vector = []
- sv_entropy_list = []
-
- # for each new image apply SVD and get SV
- for img in images:
- s = compression.get_SVD_s(img)
- sv_vector.append(s)
- sv_entropy = [utils.get_entropy_contribution_of_i(s, id_sv) for id_sv, sv in enumerate(s)]
- sv_entropy_list.append(sv_entropy)
-
- sv_std = []
-
- sv_array = np.array(sv_vector)
- _, length = sv_array.shape
-
- # normalize each SV vectors and compute standard deviation for each sub vectors
- for i in range(length):
- sv_array[:, i] = utils.normalize_arr(sv_array[:, i])
- sv_std.append(np.std(sv_array[:, i]))
-
- indices = []
- if 'lowest' in data_type:
- indices = utils.get_indices_of_lowest_values(sv_std, 200)
- if 'highest' in data_type:
- indices = utils.get_indices_of_highest_values(sv_std, 200)
- # data are arranged following std trend computed
- s_arr = compression.get_SVD_s(arr)
- data = s_arr[indices]
- if 'convolutional_kernels' in data_type:
- sub_zones = segmentation.divide_in_blocks(block, (20, 20))
- data = []
- diff_std_list_3 = []
- diff_std_list_5 = []
- diff_mean_list_3 = []
- diff_mean_list_5 = []
- plane_std_list_3 = []
- plane_std_list_5 = []
- plane_mean_list_3 = []
- plane_mean_list_5 = []
- plane_max_std_list_3 = []
- plane_max_std_list_5 = []
- plane_max_mean_list_3 = []
- plane_max_mean_list_5 = []
- for sub_zone in sub_zones:
- l_img = transform.get_LAB_L(sub_zone)
- normed_l_img = utils.normalize_2D_arr(l_img)
- # bilateral with window of size (3, 3)
- normed_diff = convolution.convolution2D(normed_l_img, kernels.bilateral_diff, (3, 3))
- std_diff = np.std(normed_diff)
- mean_diff = np.mean(normed_diff)
- diff_std_list_3.append(std_diff)
- diff_mean_list_3.append(mean_diff)
- # bilateral with window of size (5, 5)
- normed_diff = convolution.convolution2D(normed_l_img, kernels.bilateral_diff, (5, 5))
- std_diff = np.std(normed_diff)
- mean_diff = np.mean(normed_diff)
- diff_std_list_5.append(std_diff)
- diff_mean_list_5.append(mean_diff)
- # plane mean with window of size (3, 3)
- normed_plane_mean = convolution.convolution2D(normed_l_img, kernels.plane_mean, (3, 3))
- std_plane_mean = np.std(normed_plane_mean)
- mean_plane_mean = np.mean(normed_plane_mean)
- plane_std_list_3.append(std_plane_mean)
- plane_mean_list_3.append(mean_plane_mean)
- # plane mean with window of size (5, 5)
- normed_plane_mean = convolution.convolution2D(normed_l_img, kernels.plane_mean, (5, 5))
- std_plane_mean = np.std(normed_plane_mean)
- mean_plane_mean = np.mean(normed_plane_mean)
- plane_std_list_5.append(std_plane_mean)
- plane_mean_list_5.append(mean_plane_mean)
- # plane max error with window of size (3, 3)
- normed_plane_max = convolution.convolution2D(normed_l_img, kernels.plane_max_error, (3, 3))
- std_plane_max = np.std(normed_plane_max)
- mean_plane_max = np.mean(normed_plane_max)
- plane_max_std_list_3.append(std_plane_max)
- plane_max_mean_list_3.append(mean_plane_max)
- # plane max error with window of size (5, 5)
- normed_plane_max = convolution.convolution2D(normed_l_img, kernels.plane_max_error, (5, 5))
- std_plane_max = np.std(normed_plane_max)
- mean_plane_max = np.mean(normed_plane_max)
- plane_max_std_list_5.append(std_plane_max)
- plane_max_mean_list_5.append(mean_plane_max)
- diff_std_list_3 = np.array(diff_std_list_3)
- diff_std_list_5 = np.array(diff_std_list_5)
- diff_mean_list_3 = np.array(diff_mean_list_3)
- diff_mean_list_5 = np.array(diff_mean_list_5)
- plane_std_list_3 = np.array(plane_std_list_3)
- plane_std_list_5 = np.array(plane_std_list_5)
- plane_mean_list_3 = np.array(plane_mean_list_3)
- plane_mean_list_5 = np.array(plane_mean_list_5)
- plane_max_std_list_3 = np.array(plane_max_std_list_3)
- plane_max_std_list_5 = np.array(plane_max_std_list_5)
- plane_max_mean_list_3 = np.array(plane_max_mean_list_3)
- plane_max_mean_list_5 = np.array(plane_max_mean_list_5)
- if 'std_max_blocks' in data_type:
- data.append(np.std(diff_std_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.std(diff_mean_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.std(diff_std_list_5[0:int(len(sub_zones)/5)]))
- data.append(np.std(diff_mean_list_5[0:int(len(sub_zones)/5)]))
- data.append(np.std(plane_std_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.std(plane_mean_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.std(plane_std_list_5[0:int(len(sub_zones)/5)]))
- data.append(np.std(plane_mean_list_5[0:int(len(sub_zones)/5)]))
- data.append(np.std(plane_max_std_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.std(plane_max_mean_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.std(plane_max_std_list_5[0:int(len(sub_zones)/5)]))
- data.append(np.std(plane_max_mean_list_5[0:int(len(sub_zones)/5)]))
- if 'mean_max_blocks' in data_type:
- data.append(np.mean(diff_std_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.mean(diff_mean_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.mean(diff_std_list_5[0:int(len(sub_zones)/5)]))
- data.append(np.mean(diff_mean_list_5[0:int(len(sub_zones)/5)]))
- data.append(np.mean(plane_std_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.mean(plane_mean_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.mean(plane_std_list_5[0:int(len(sub_zones)/5)]))
- data.append(np.mean(plane_mean_list_5[0:int(len(sub_zones)/5)]))
-
- data.append(np.mean(plane_max_std_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.mean(plane_max_mean_list_3[0:int(len(sub_zones)/5)]))
- data.append(np.mean(plane_max_std_list_5[0:int(len(sub_zones)/5)]))
- data.append(np.mean(plane_max_mean_list_5[0:int(len(sub_zones)/5)]))
- if 'std_normed' in data_type:
- data.append(np.std(diff_std_list_3))
- data.append(np.std(diff_mean_list_3))
- data.append(np.std(diff_std_list_5))
- data.append(np.std(diff_mean_list_5))
- data.append(np.std(plane_std_list_3))
- data.append(np.std(plane_mean_list_3))
- data.append(np.std(plane_std_list_5))
- data.append(np.std(plane_mean_list_5))
-
- data.append(np.std(plane_max_std_list_3))
- data.append(np.std(plane_max_mean_list_3))
- data.append(np.std(plane_max_std_list_5))
- data.append(np.std(plane_max_mean_list_5))
- if 'mean_normed' in data_type:
- data.append(np.mean(diff_std_list_3))
- data.append(np.mean(diff_mean_list_3))
- data.append(np.mean(diff_std_list_5))
- data.append(np.mean(diff_mean_list_5))
- data.append(np.mean(plane_std_list_3))
- data.append(np.mean(plane_mean_list_3))
- data.append(np.mean(plane_std_list_5))
- data.append(np.mean(plane_mean_list_5))
-
- data.append(np.mean(plane_max_std_list_3))
- data.append(np.mean(plane_max_mean_list_3))
- data.append(np.mean(plane_max_std_list_5))
- data.append(np.mean(plane_max_mean_list_5))
- data = np.array(data)
- if data_type == 'convolutional_kernel_stats_svd':
- l_img = transform.get_LAB_L(block)
- normed_l_img = utils.normalize_2D_arr(l_img)
- # bilateral with window of size (5, 5)
- normed_diff = convolution.convolution2D(normed_l_img, kernels.bilateral_diff, (5, 5))
- # getting sigma vector from SVD compression
- s = compression.get_SVD_s(normed_diff)
- data = s
-
- return data
- def w2d(arr, mode='haar', level=1):
- #convert to float
- imArray = arr
- np.divide(imArray, 255)
- # compute coefficients
- coeffs=pywt.wavedec2(imArray, mode, level=level)
- #Process Coefficients
- coeffs_H=list(coeffs)
- coeffs_H[0] *= 0
- # reconstruction
- imArray_H = pywt.waverec2(coeffs_H, mode)
- imArray_H *= 255
- imArray_H = np.uint8(imArray_H)
- return imArray_H
- def _get_mscn_variance(block, sub_block_size=(50, 50)):
- blocks = segmentation.divide_in_blocks(block, sub_block_size)
- data = []
- for block in blocks:
- mscn_coefficients = transform.get_mscn_coefficients(block)
- flat_coeff = mscn_coefficients.flatten()
- data.append(np.var(flat_coeff))
- return np.sort(data)
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