from ipfml import processing, metrics, utils from modules.utils.config import * 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 import numpy as np _scenes_names_prefix = '_scenes_names' _scenes_indices_prefix = '_scenes_indices' # store all variables from current module context context_vars = vars() def get_svd_data(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 = processing.get_LAB_L_SVD_s(Image.open(block_file_path)) if data_type == 'mscn': img_mscn_revisited = processing.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 = metrics.get_SVD_s(img_block) """if data_type == 'mscn': img_gray = np.array(color.rgb2gray(np.asarray(block))*255, 'uint8') img_mscn = processing.calculate_mscn_coefficients(img_gray, 7) img_mscn_norm = processing.normalize_2D_arr(img_mscn) img_mscn_gray = np.array(img_mscn_norm*255, 'uint8') data = metrics.get_SVD_s(img_mscn_gray) """ if data_type == 'low_bits_6': low_bits_6 = processing.rgb_to_LAB_L_low_bits(block, 6) data = metrics.get_SVD_s(low_bits_6) if data_type == 'low_bits_5': low_bits_5 = processing.rgb_to_LAB_L_low_bits(block, 5) data = metrics.get_SVD_s(low_bits_5) if data_type == 'low_bits_4': low_bits_4 = processing.rgb_to_LAB_L_low_bits(block, 4) data = metrics.get_SVD_s(low_bits_4) if data_type == 'low_bits_3': low_bits_3 = processing.rgb_to_LAB_L_low_bits(block, 3) data = metrics.get_SVD_s(low_bits_3) if data_type == 'low_bits_2': low_bits_2 = processing.rgb_to_LAB_L_low_bits(block, 2) data = metrics.get_SVD_s(low_bits_2) if data_type == 'low_bits_4_shifted_2': data = metrics.get_SVD_s(processing.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 = processing.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(processing.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 = processing.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(processing.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 = processing.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(processing.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 = processing.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(processing.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 = metrics.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(metrics.get_SVD_s(current_image)) ica_sv_values = utils.normalize_arr(metrics.get_SVD_s(final_image)) data = abs(np.array(sv_values) - np.array(ica_sv_values)) if data_type == 'svd_trunc_diff': current_image = metrics.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 = metrics.get_SVD(reduced_image) data = s if data_type == 'ipca_diff': current_image = metrics.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 = metrics.get_SVD(reduced_image) data = s if data_type == 'svd_reconstruct': reconstructed_interval = (90, 200) begin, end = reconstructed_interval lab_img = metrics.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 = metrics.get_SVD_s(output_img) return data def _get_mscn_variance(block, sub_block_size=(50, 50)): blocks = processing.divide_in_blocks(block, sub_block_size) data = [] for block in blocks: mscn_coefficients = processing.get_mscn_coefficients(block) flat_coeff = mscn_coefficients.flatten() data.append(np.var(flat_coeff)) return np.sort(data) def get_renderer_scenes_indices(renderer_name): if renderer_name not in renderer_choices: raise ValueError("Unknown renderer name") if renderer_name == 'all': return scenes_indices else: return context_vars[renderer_name + _scenes_indices_prefix] def get_renderer_scenes_names(renderer_name): if renderer_name not in renderer_choices: raise ValueError("Unknown renderer name") if renderer_name == 'all': return scenes_names else: return context_vars[renderer_name + _scenes_names_prefix]