def decode_embedding_input(latent, shape, name, large=False): conv1_size = 128 if large else 64 latent = Reshape((1, INNER_SIZE))(latent) conv1 = Conv1D(conv1_size, (1,), activation='mish', padding='same', name=name + '_conv1')(latent) up1 = UpSampling1D(shape[0], name=name + '_up1')(conv1) conv2 = Conv1D(shape[1], (6,), activation='mish', padding='same', name=name + '_conv2')(up1) return conv2
def create_convolutional_decoder(encoder): conv1 = Conv1D(filters=32, kernel_size=42, activation='relu', input_shape=(INPUT_LENGTH, 1))(input_shape) conv1 = UpSampling1D(pool_size=10)(conv1) conv1 = BatchNormalization()(conv1) conv2 = Conv1D(filters=64, kernel_size=59, activation='relu')(conv1) conv2 = MaxPooling1D(pool_size=10)(conv2) conv2 = BatchNormalization()(conv2) return conv2
def decode_embedding_input(embedding, shape, type='subject', ): conv1_size = CONV_SIZES[type][0] embedding = Reshape((1, INNER_SIZE))(embedding) if type == 'relation': conv1 = Conv1D(conv1_size, (1,), activation=mish, padding='same', name='output_' + type + '_conv1')( embedding) up1 = UpSampling1D(shape[0], name='output_' + type + '_up1')(conv1) conv2 = Conv1D(shape[1], (3,), activation=mish, padding='same', name='output_' + type + '_conv2')(up1) return conv2 conv1 = Conv1D(shape[1], (2,), activation=mish, padding='same', name='output_' + type + '_conv1')(embedding) return conv1
def test_delete_channels_upsampling1d(channel_index): layer = UpSampling1D(3) layer_test_helper_flatten_1d(layer, channel_index)
def decode_embedding_input(latent, name): latent = Reshape((1, INNER_SIZE))(latent) conv1 = Conv1D(128, (1,), activation='relu', padding='same', name=name + '_conv1')(latent) up1 = UpSampling1D(input_shape[0], name=name + '_up1')(conv1) conv2 = Conv1D(input_shape[1], (6,), activation='relu', padding='same', name=name + '_conv2')(up1) return conv2
def get_test_model_full(): """Returns a maximally complex test model, using all supported layer types with different parameter combination. """ input_shapes = [ (26, 28, 3), (4, 4, 3), (4, 4, 3), (4, ), (2, 3), (27, 29, 1), (17, 1), (17, 4), ] inputs = [Input(shape=s) for s in input_shapes] outputs = [] for inp in inputs[6:8]: for padding in ['valid', 'same']: for s in range(1, 6): for out_channels in [1, 2]: for d in range(1, 4): outputs.append( Conv1D(out_channels, s, padding=padding, dilation_rate=d)(inp)) for padding_size in range(0, 5): outputs.append(ZeroPadding1D(padding_size)(inp)) for crop_left in range(0, 2): for crop_right in range(0, 2): outputs.append(Cropping1D((crop_left, crop_right))(inp)) for upsampling_factor in range(1, 5): outputs.append(UpSampling1D(upsampling_factor)(inp)) for padding in ['valid', 'same']: for pool_factor in range(1, 6): for s in range(1, 4): outputs.append( MaxPooling1D(pool_factor, strides=s, padding=padding)(inp)) outputs.append( AveragePooling1D(pool_factor, strides=s, padding=padding)(inp)) outputs.append(GlobalMaxPooling1D()(inp)) outputs.append(GlobalAveragePooling1D()(inp)) for inp in [inputs[0], inputs[5]]: for padding in ['valid', 'same']: for h in range(1, 6): for out_channels in [1, 2]: for d in range(1, 4): outputs.append( Conv2D(out_channels, (h, 1), padding=padding, dilation_rate=(d, 1))(inp)) outputs.append( SeparableConv2D(out_channels, (h, 1), padding=padding, dilation_rate=(d, 1))(inp)) for sy in range(1, 4): outputs.append( Conv2D(out_channels, (h, 1), strides=(1, sy), padding=padding)(inp)) outputs.append( SeparableConv2D(out_channels, (h, 1), strides=(sy, sy), padding=padding)(inp)) for sy in range(1, 4): outputs.append( MaxPooling2D((h, 1), strides=(1, sy), padding=padding)(inp)) for w in range(1, 6): for out_channels in [1, 2]: for d in range(1, 4) if sy == 1 else [1]: outputs.append( Conv2D(out_channels, (1, w), padding=padding, dilation_rate=(1, d))(inp)) outputs.append( SeparableConv2D(out_channels, (1, w), padding=padding, dilation_rate=(1, d))(inp)) for sx in range(1, 4): outputs.append( Conv2D(out_channels, (1, w), strides=(sx, 1), padding=padding)(inp)) outputs.append( SeparableConv2D(out_channels, (1, w), strides=(sx, sx), padding=padding)(inp)) for sx in range(1, 4): outputs.append( MaxPooling2D((1, w), strides=(1, sx), padding=padding)(inp)) outputs.append(ZeroPadding2D(2)(inputs[0])) outputs.append(ZeroPadding2D((2, 3))(inputs[0])) outputs.append(ZeroPadding2D(((1, 2), (3, 4)))(inputs[0])) outputs.append(Cropping2D(2)(inputs[0])) outputs.append(Cropping2D((2, 3))(inputs[0])) outputs.append(Cropping2D(((1, 2), (3, 4)))(inputs[0])) for y in range(1, 3): for x in range(1, 3): outputs.append(UpSampling2D(size=(y, x))(inputs[0])) outputs.append(GlobalAveragePooling2D()(inputs[0])) outputs.append(GlobalMaxPooling2D()(inputs[0])) outputs.append(AveragePooling2D((2, 2))(inputs[0])) outputs.append(MaxPooling2D((2, 2))(inputs[0])) outputs.append(UpSampling2D((2, 2))(inputs[0])) outputs.append(keras.layers.concatenate([inputs[0], inputs[0]])) outputs.append(Dropout(0.5)(inputs[0])) outputs.append(BatchNormalization()(inputs[0])) outputs.append(BatchNormalization(center=False)(inputs[0])) outputs.append(BatchNormalization(scale=False)(inputs[0])) outputs.append(Conv2D(2, (3, 3), use_bias=True)(inputs[0])) outputs.append(Conv2D(2, (3, 3), use_bias=False)(inputs[0])) outputs.append(SeparableConv2D(2, (3, 3), use_bias=True)(inputs[0])) outputs.append(SeparableConv2D(2, (3, 3), use_bias=False)(inputs[0])) outputs.append(Dense(2, use_bias=True)(inputs[3])) outputs.append(Dense(2, use_bias=False)(inputs[3])) shared_conv = Conv2D(1, (1, 1), padding='valid', name='shared_conv', activation='relu') up_scale_2 = UpSampling2D((2, 2)) x1 = shared_conv(up_scale_2(inputs[1])) # (1, 8, 8) x2 = shared_conv(up_scale_2(inputs[2])) # (1, 8, 8) x3 = Conv2D(1, (1, 1), padding='valid')(up_scale_2(inputs[2])) # (1, 8, 8) x = keras.layers.concatenate([x1, x2, x3]) # (3, 8, 8) outputs.append(x) x = Conv2D(3, (1, 1), padding='same', use_bias=False)(x) # (3, 8, 8) outputs.append(x) x = Dropout(0.5)(x) outputs.append(x) x = keras.layers.concatenate( [MaxPooling2D((2, 2))(x), AveragePooling2D((2, 2))(x)]) # (6, 4, 4) outputs.append(x) x = Flatten()(x) # (1, 1, 96) x = Dense(4, use_bias=False)(x) outputs.append(x) x = Dense(3)(x) # (1, 1, 3) outputs.append(x) intermediate_input_shape = (3, ) intermediate_in = Input(intermediate_input_shape) intermediate_x = intermediate_in intermediate_x = Dense(8)(intermediate_x) intermediate_x = Dense(5)(intermediate_x) intermediate_model = Model(inputs=[intermediate_in], outputs=[intermediate_x], name='intermediate_model') intermediate_model.compile(loss='mse', optimizer='nadam') x = intermediate_model(x) # (1, 1, 5) intermediate_model_2 = Sequential() intermediate_model_2.add(Dense(7, input_shape=(5, ))) intermediate_model_2.add(Dense(5)) intermediate_model_2.compile(optimizer='rmsprop', loss='categorical_crossentropy') x = intermediate_model_2(x) # (1, 1, 5) x = Dense(3)(x) # (1, 1, 3) shared_activation = Activation('tanh') outputs = outputs + [ Activation('tanh')(inputs[3]), Activation('hard_sigmoid')(inputs[3]), Activation('selu')(inputs[3]), Activation('sigmoid')(inputs[3]), Activation('softplus')(inputs[3]), Activation('softmax')(inputs[3]), Activation('relu')(inputs[3]), LeakyReLU()(inputs[3]), ELU()(inputs[3]), shared_activation(inputs[3]), inputs[4], inputs[1], x, shared_activation(x), ] print('Model has {} outputs.'.format(len(outputs))) model = Model(inputs=inputs, outputs=outputs, name='test_model_full') model.compile(loss='mse', optimizer='nadam') # fit to dummy data training_data_size = 1 batch_size = 1 epochs = 10 data_in = generate_input_data(training_data_size, input_shapes) data_out = generate_output_data(training_data_size, outputs) model.fit(data_in, data_out, epochs=epochs, batch_size=batch_size) return model