import numpy as np from nnlib import nnlib from models import ModelBase from facelib import FaceType from samples import * from utils.console_utils import * #SAE - Styled AutoEncoder class SAEModel(ModelBase): encoderH5 = 'encoder.h5' inter_BH5 = 'inter_B.h5' inter_ABH5 = 'inter_AB.h5' decoderH5 = 'decoder.h5' decodermH5 = 'decoderm.h5' #override def onInitializeOptions(self, is_first_run, ask_for_session_options): default_resolution = 128 default_ae_dims = 256 default_face_type = 'f' if is_first_run: #first run self.options['resolution'] = input_int("Resolution (valid: 64,128, skip:128) : ", default_resolution, [64,128]) self.options['ae_dims'] = input_int("AutoEncoder dims (valid: 128,256,512 skip:256) : ", default_ae_dims, [128,256,512]) self.options['face_type'] = input_str ("Half or Full face? (h/f, skip:f) : ", default_face_type, ['h','f']) else: #not first run self.options['resolution'] = self.options.get('resolution', default_resolution) self.options['ae_dims'] = self.options.get('ae_dims', default_ae_dims) self.options['face_type'] = self.options.get('face_type', default_face_type) #override def onInitialize(self, **in_options): exec(nnlib.import_all(), locals(), globals()) self.set_vram_batch_requirements({2:2,3:3,4:4,5:4,6:8,7:12,8:16}) resolution = self.options['resolution'] ae_dims = self.options['ae_dims'] bgr_shape = (resolution, resolution, 3) mask_shape = (resolution, resolution, 1) self.encoder = modelify(SAEModel.EncFlow() ) (Input(bgr_shape)) enc_output_Inputs = [ Input(K.int_shape(x)[1:]) for x in self.encoder.outputs ] self.inter_B = modelify(SAEModel.InterFlow(dims=ae_dims,lowest_dense_res=resolution // 16)) (enc_output_Inputs) self.inter_AB = modelify(SAEModel.InterFlow(dims=ae_dims,lowest_dense_res=resolution // 16)) (enc_output_Inputs) inter_output_Inputs = [ Input( np.array(K.int_shape(x)[1:])*(1,1,2) ) for x in self.inter_B.outputs ] self.decoder = modelify(SAEModel.DecFlow (bgr_shape[2],dims=ae_dims*2)) (inter_output_Inputs) self.decoderm = modelify(SAEModel.DecFlow (mask_shape[2],dims=ae_dims)) (inter_output_Inputs) if not self.is_first_run(): self.encoder.load_weights (self.get_strpath_storage_for_file(self.encoderH5)) self.inter_B.load_weights (self.get_strpath_storage_for_file(self.inter_BH5)) self.inter_AB.load_weights (self.get_strpath_storage_for_file(self.inter_ABH5)) self.decoder.load_weights (self.get_strpath_storage_for_file(self.decoderH5)) self.decoderm.load_weights (self.get_strpath_storage_for_file(self.decodermH5)) warped_src = Input(bgr_shape) target_src = Input(bgr_shape) target_srcm = Input(mask_shape) warped_src_code = self.encoder (warped_src) warped_src_inter_AB_code = self.inter_AB (warped_src_code) warped_src_inter_code = Concatenate()([warped_src_inter_AB_code,warped_src_inter_AB_code]) pred_src_src = self.decoder(warped_src_inter_code) pred_src_srcm = self.decoderm(warped_src_inter_code) warped_dst = Input(bgr_shape) target_dst = Input(bgr_shape) target_dstm = Input(mask_shape) warped_dst_code = self.encoder (warped_dst) warped_dst_inter_B_code = self.inter_B (warped_dst_code) warped_dst_inter_AB_code = self.inter_AB (warped_dst_code) warped_dst_inter_code = Concatenate()([warped_dst_inter_B_code,warped_dst_inter_AB_code]) pred_dst_dst = self.decoder(warped_dst_inter_code) pred_dst_dstm = self.decoderm(warped_dst_inter_code) warped_src_dst_inter_code = Concatenate()([warped_dst_inter_AB_code,warped_dst_inter_AB_code]) pred_src_dst = self.decoder(warped_src_dst_inter_code) pred_src_dstm = self.decoderm(warped_src_dst_inter_code) target_srcm_blurred = tf_gaussian_blur(resolution // 32)(target_srcm) target_srcm_sigm = target_srcm_blurred / 2.0 + 0.5 target_srcm_anti_sigm = 1.0 - target_srcm_sigm target_dstm_blurred = tf_gaussian_blur(resolution // 32)(target_dstm) target_dstm_sigm = target_dstm_blurred / 2.0 + 0.5 target_dstm_anti_sigm = 1.0 - target_dstm_sigm target_src_sigm = target_src+1 target_dst_sigm = target_dst+1 pred_src_src_sigm = pred_src_src+1 pred_dst_dst_sigm = pred_dst_dst+1 pred_src_dst_sigm = pred_src_dst+1 pred_src_dstm_blurred = tf_gaussian_blur(resolution // 32)(pred_src_dstm) pred_src_dstm_sigm = pred_src_dstm_blurred / 2.0 + 0.5 pred_src_dstm_anti_sigm = 1.0 - pred_src_dstm_sigm target_src_masked = target_src_sigm*target_srcm_sigm target_dst_masked = target_dst_sigm * target_dstm_sigm target_dst_anti_masked = target_dst_sigm * target_dstm_anti_sigm target_dst_psd_masked = target_dst_sigm * pred_src_dstm_sigm target_dst_psd_anti_masked = target_dst_sigm * pred_src_dstm_anti_sigm pred_src_src_masked = pred_src_src_sigm * target_srcm_sigm pred_dst_dst_masked = pred_dst_dst_sigm * target_dstm_sigm psd_target_dst_masked = pred_src_dst_sigm * target_dstm_sigm psd_target_dst_anti_masked = pred_src_dst_sigm * target_dstm_anti_sigm psd_psd_masked = pred_src_dst_sigm * pred_src_dstm_sigm psd_psd_anti_masked = pred_src_dst_sigm * pred_src_dstm_anti_sigm src_loss = K.mean( 100*K.square(tf_dssim(2.0)( target_src_masked, pred_src_src_masked )) ) src_loss += tf_style_loss(gaussian_blur_radius=resolution // 8, loss_weight=0.2)(psd_target_dst_masked, target_dst_masked) src_loss += K.mean( 100*K.square(tf_dssim(2.0)( psd_target_dst_anti_masked, target_dst_anti_masked ))) #src_loss += tf_style_loss(gaussian_blur_radius=resolution // 8, loss_weight=0.2)(psd_psd_masked, target_dst_psd_masked) #src_loss += K.mean( 100*K.square(tf_dssim(2.0)( psd_psd_anti_masked, target_dst_psd_anti_masked ))) self.src_train = K.function ([warped_src, target_src, target_srcm, warped_dst, target_dst, target_dstm ],[src_loss], Adam(lr=5e-5, beta_1=0.5, beta_2=0.999).get_updates(src_loss, self.encoder.trainable_weights + self.inter_AB.trainable_weights + self.decoder.trainable_weights) ) dst_loss = K.mean( 100*K.square(tf_dssim(2.0)( target_dst_masked, pred_dst_dst_masked )) ) self.dst_train = K.function ([warped_dst, target_dst, target_dstm],[dst_loss], Adam(lr=5e-5, beta_1=0.5, beta_2=0.999).get_updates(dst_loss, self.encoder.trainable_weights + self.inter_B.trainable_weights + self.inter_AB.trainable_weights + self.decoder.trainable_weights) ) src_mask_loss = K.mean(K.square(target_srcm-pred_src_srcm)) self.src_mask_train = K.function ([warped_src, target_srcm],[src_mask_loss], Adam(lr=5e-5, beta_1=0.5, beta_2=0.999).get_updates(src_mask_loss, self.encoder.trainable_weights + self.inter_AB.trainable_weights + self.decoderm.trainable_weights) ) dst_mask_loss = K.mean(K.square(target_dstm-pred_dst_dstm)) self.dst_mask_train = K.function ([warped_dst, target_dstm],[dst_mask_loss], Adam(lr=5e-5, beta_1=0.5, beta_2=0.999).get_updates(dst_mask_loss, self.encoder.trainable_weights + self.inter_B.trainable_weights + self.inter_AB.trainable_weights + self.decoderm.trainable_weights) ) self.AE_view = K.function ([warped_src, warped_dst],[pred_src_src, pred_src_srcm, pred_dst_dst, pred_dst_dstm, pred_src_dst, pred_src_dstm]) self.AE_convert = K.function ([warped_dst],[pred_src_dst, pred_src_dstm]) if self.is_training_mode: f = SampleProcessor.TypeFlags face_type = f.FACE_ALIGN_FULL if self.options['face_type'] == 'f' else f.FACE_ALIGN_HALF self.set_training_data_generators ([ SampleGeneratorFace(self.training_data_src_path, sort_by_yaw_target_samples_path=self.training_data_dst_path if self.sort_by_yaw else None, debug=self.is_debug(), batch_size=self.batch_size, sample_process_options=SampleProcessor.Options(random_flip=self.random_flip, normalize_tanh = True), output_sample_types=[ [f.WARPED_TRANSFORMED | face_type | f.MODE_BGR, resolution], [f.TRANSFORMED | face_type | f.MODE_BGR, resolution], [f.TRANSFORMED | face_type | f.MODE_M | f.FACE_MASK_FULL, resolution], # ] ), SampleGeneratorFace(self.training_data_dst_path, debug=self.is_debug(), batch_size=self.batch_size, sample_process_options=SampleProcessor.Options(random_flip=self.random_flip, normalize_tanh = True), output_sample_types=[ [f.WARPED_TRANSFORMED | face_type | f.MODE_BGR, resolution], [f.TRANSFORMED | face_type | f.MODE_BGR, resolution], [f.TRANSFORMED | face_type | f.MODE_M | f.FACE_MASK_FULL, resolution] ] ) ]) #override def onSave(self): self.save_weights_safe( [[self.encoder, self.get_strpath_storage_for_file(self.encoderH5)], [self.inter_B, self.get_strpath_storage_for_file(self.inter_BH5)], [self.inter_AB, self.get_strpath_storage_for_file(self.inter_ABH5)], [self.decoder, self.get_strpath_storage_for_file(self.decoderH5)], [self.decoderm, self.get_strpath_storage_for_file(self.decodermH5)], ] ) #override def onTrainOneEpoch(self, sample): warped_src, target_src, target_src_mask = sample[0] warped_dst, target_dst, target_dst_mask = sample[1] src_loss, = self.src_train ([warped_src, target_src, target_src_mask, warped_dst, target_dst, target_dst_mask]) dst_loss, = self.dst_train ([warped_dst, target_dst, target_dst_mask]) src_mask_loss, = self.src_mask_train ([warped_src, target_src_mask]) dst_mask_loss, = self.dst_mask_train ([warped_dst, target_dst_mask]) return ( ('src_loss', src_loss), ('dst_loss', dst_loss) ) #override def onGetPreview(self, sample): test_A = sample[0][1][0:4] #first 4 samples test_A_m = sample[0][2][0:4] #first 4 samples test_B = sample[1][1][0:4] test_B_m = sample[1][2][0:4] S = test_A D = test_B SS, SM, DD, DM, SD, SDM = self.AE_view ([test_A, test_B]) S, D, SS, SM, DD, DM, SD, SDM = [ x / 2 + 0.5 for x in [S, D, SS, SM, DD, DM, SD, SDM] ] SM, DM, SDM = [ np.repeat (x, (3,), -1) for x in [SM, DM, SDM] ] st = [] for i in range(0, len(test_A)): st.append ( np.concatenate ( ( S[i], SS[i], #SM[i], D[i], DD[i], #DM[i], SD[i], #SDM[i] ), axis=1) ) return [ ('SAE', np.concatenate ( st, axis=0 ) ) ] def predictor_func (self, face): face = face * 2.0 - 1.0 face_128_bgr = face[...,0:3] x, mx = [ (x[0] + 1.0) / 2.0 for x in self.AE_convert ( [ np.expand_dims(face_128_bgr,0) ] ) ] return np.concatenate ( (x,mx), -1 ) #override def get_converter(self, **in_options): from models import ConverterMasked base_erode_mask_modifier = 40 if self.options['face_type'] == 'f' else 100 base_blur_mask_modifier = 10 if self.options['face_type'] == 'f' else 100 face_type = FaceType.FULL if self.options['face_type'] == 'f' else FaceType.HALF return ConverterMasked(self.predictor_func, predictor_input_size=self.options['resolution'], output_size=self.options['resolution'], face_type=face_type, base_erode_mask_modifier=base_erode_mask_modifier, base_blur_mask_modifier=base_blur_mask_modifier, **in_options) @staticmethod def EncFlow(): exec (nnlib.import_all(), locals(), globals()) def downscale (dim): def func(x): return LeakyReLU(0.1)(Conv2D(dim, 5, strides=2, padding='same')(x)) return func def upscale (dim): def func(x): return SubpixelUpscaler()(LeakyReLU(0.1)(Conv2D(dim * 4, 3, strides=1, padding='same')(x))) return func def func(input): x = input x = downscale(128)(x) x = downscale(256)(x) x = downscale(512)(x) x = downscale(1024)(x) x = Flatten()(x) return x return func @staticmethod def InterFlow(dims=256, lowest_dense_res=8): exec (nnlib.import_all(), locals(), globals()) def upscale (dim): def func(x): return SubpixelUpscaler()(LeakyReLU(0.1)(Conv2D(dim * 4, 3, strides=1, padding='same')(x))) return func def func(input): x = input[0] x = Dense(dims)(x) x = Dense(lowest_dense_res * lowest_dense_res * dims*2)(x) x = Reshape((lowest_dense_res, lowest_dense_res, dims*2))(x) x = upscale(dims*2)(x) return x return func @staticmethod def DecFlow(output_nc,dims,activation='tanh'): exec (nnlib.import_all(), locals(), globals()) def upscale (dim): def func(x): return SubpixelUpscaler()(LeakyReLU(0.1)(Conv2D(dim * 4, 3, strides=1, padding='same')(x))) return func def func(input): x = input[0] x = upscale(dims)(x) x = upscale(dims//2)(x) x = upscale(dims//4)(x) x = Conv2D(output_nc, kernel_size=5, padding='same', activation=activation)(x) return x return func Model = SAEModel