context("layers") test_call_succeeds("layer_input", { layer_input(shape = c(32)) input <- layer_input(shape = c(32), sparse = TRUE) # TODO: arg rename: ragged -> sparse }) test_call_succeeds("layer_dense", { layer_dense(keras_model_sequential(), 32, input_shape = c(784)) }) test_call_succeeds("layer_activation", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_activation('relu') }) test_call_succeeds("layer_activation_relu", required_version = "2.2.0", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_activation_relu() }) test_call_succeeds("layer_activation_selu", required_version = "2.2.0", { skip("layer_activation_selu") keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_activation_selu() }) test_call_succeeds("layer_activation_leaky_relu", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_activation_leaky_relu() }) test_call_succeeds("layer_activation_parametric_relu", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_activation_parametric_relu() }) test_call_succeeds("layer_activation_elu", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_activation_elu() }) test_call_succeeds("layer_activity_regularization", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_activity_regularization() }) test_call_succeeds("layer_dropout", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_dropout(rate = 0.5, noise_shape = c(1)) }) test_call_succeeds("layer_spatial_dropout_1d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_spatial_dropout_1d(rate = 0.5) }) test_call_succeeds("layer_spatial_dropout_2d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_spatial_dropout_2d(rate = 0.5) }) test_call_succeeds("layer_spatial_dropout_3d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,2,2,4)) %>% layer_spatial_dropout_3d(rate = 0.5) }) test_call_succeeds("layer_lambda", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_lambda(function(t) t, output_shape = c(784)) }) test_call_succeeds("layer_masking", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_masking(mask_value = 0.5) }) test_call_succeeds("layer_repeat_vector", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_repeat_vector(3) }) test_call_succeeds("layer_reshape", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) }) test_call_succeeds("layer_permute", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_permute(dims = c(1)) }) test_call_succeeds("layer_flatten", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_flatten() }) test_call_succeeds("layer_conv_1d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_conv_1d(filters = 3, kernel_size = 2) }) test_call_succeeds("layer_conv_2d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_conv_2d(filters = 3, kernel_size = c(2, 2)) }) test_call_succeeds("layer_conv_3d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,2,2,4)) %>% layer_conv_3d(filters = 3, kernel_size = c(2, 2, 2)) }) test_call_succeeds("layer_conv_1d_transpose", { if (tensorflow::tf_version() < "2.3") skip("Needs TF >= 2.3") keras_model_sequential() %>% layer_dense(32, input_shape = 100) %>% layer_reshape(target_shape = c(8,4)) %>% layer_conv_1d_transpose(filters = 3, kernel_size = 2) }) test_call_succeeds("layer_conv_2d_transpose", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_conv_2d_transpose(filters = 3, kernel_size = c(2, 2)) }) test_call_succeeds("layer_conv_3d_transpose", required_version = "2.0.6", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,2,2,4)) %>% layer_conv_3d_transpose(filters = 3, kernel_size = c(2, 2, 2)) }) test_call_succeeds("layer_separable_conv_2d", { if (is_tensorflow_implementation()) { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_separable_conv_2d(filters = 4, kernel_size = c(2,2)) } }) test_call_succeeds("layer_depthwise_conv_2d", required_version = "2.1.5", { if (is_tensorflow_implementation()) { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_depthwise_conv_2d(kernel_size = c(2,2)) } }) if(tf_version() >= "2.8") test_call_succeeds("layer_depthwise_conv_1d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(4, -1)) %>% layer_depthwise_conv_1d(kernel_size = 2) }) if(tf_version() >= "2.6") test_call_succeeds("layer_conv_lstm_1d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_conv_lstm_1d(filters = 3, kernel_size = c(2)) }) test_call_succeeds("layer_conv_lstm_2d", { keras_model_sequential() %>% layer_dense(16, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,2,2,2)) %>% layer_conv_lstm_2d(filters = 3, kernel_size = c(1, 1)) }) if(tf_version() >= "2.6") test_call_succeeds("layer_conv_lstm_3d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,2,2,2,2)) %>% layer_conv_lstm_3d(filters = 3, kernel_size = c(1, 1, 2)) }) test_call_succeeds("layer_upsampling_1d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_upsampling_1d() }) test_call_succeeds("layer_upsampling_2d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_upsampling_2d() }) test_call_succeeds("layer_upsampling_3d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,2,2)) %>% layer_upsampling_3d() }) test_call_succeeds("layer_zero_padding_1d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_zero_padding_1d() }) test_call_succeeds("layer_zero_padding_2d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_zero_padding_2d() }) test_call_succeeds("layer_zero_padding_3d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,2,2)) %>% layer_zero_padding_3d() }) test_call_succeeds("layer_cropping_1d", { skip_if_cntk() # crashes CNTK keras_model_sequential() %>% layer_dense(64, input_shape = c(784)) %>% layer_reshape(target_shape = c(4,16)) %>% layer_cropping_1d() }) test_call_succeeds("layer_cropping_2d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_cropping_2d() }) test_call_succeeds("layer_cropping_3d", { keras_model_sequential() %>% layer_dense(32*4, input_shape = c(784)) %>% layer_reshape(target_shape = c(4,4,4,2)) %>% layer_cropping_3d() }) test_call_succeeds("layer_max_pooling_1d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_max_pooling_1d() }) test_call_succeeds("layer_max_pooling_2d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_max_pooling_2d() }) test_call_succeeds("layer_max_pooling_3d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,2,2,4)) %>% layer_max_pooling_3d() }) test_call_succeeds("layer_average_pooling_1d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_average_pooling_1d(2) }) test_call_succeeds("layer_average_pooling_2d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_average_pooling_2d(c(2, 2)) }) test_call_succeeds("layer_average_pooling_3d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,2,2,4)) %>% layer_average_pooling_3d(c(2, 2, 2)) }) test_call_succeeds("layer_global_average_pooling_1d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_global_average_pooling_1d() }) test_call_succeeds("layer_global_average_pooling_2d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_global_average_pooling_2d() }) test_call_succeeds("layer_global_average_pooling_3d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,2,2,4)) %>% layer_global_average_pooling_3d() }) test_call_succeeds("layer_global_max_pooling_1d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_global_max_pooling_1d() }) test_call_succeeds("layer_global_max_pooling_2d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,4,4)) %>% layer_global_max_pooling_2d() }) test_call_succeeds("layer_global_max_pooling_3d", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,2,2,4)) %>% layer_global_max_pooling_3d() }) test_call_succeeds("layer_simple_rnn", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_simple_rnn(units = 2) }) test_call_succeeds("layer_gru", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_gru(units = 2) }) test_call_succeeds("layer_lstm", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_lstm(units = 2) }) test_call_succeeds("layer_embedding", { skip("layer_embedding() upstream doc example errors") keras_model_sequential() %>% layer_embedding(1000, 64, input_length = 10) }) get_merge_inputs <- function() { c(layer_input(shape = c(4, 5)), layer_input(shape = c(4, 5)), layer_input(shape = c(4, 5))) } test_call_succeeds("layer_add", { merge_inputs <- get_merge_inputs() output <- layer_add(merge_inputs) keras_model(merge_inputs, output) output <- layer_add()(merge_inputs) keras_model(merge_inputs, output) }) test_call_succeeds(required_version = "2.0.7", "layer_subtract", { merge_inputs <- c(layer_input(shape = c(4, 5)), layer_input(shape = c(4, 5))) output <- layer_subtract(merge_inputs) keras_model(merge_inputs, output) output <- layer_subtract()(merge_inputs) keras_model(merge_inputs, output) }) test_call_succeeds("layer_multiply", { merge_inputs <- get_merge_inputs() output <- layer_multiply(merge_inputs) keras_model(merge_inputs, output) output <- layer_multiply()(merge_inputs) keras_model(merge_inputs, output) }) test_call_succeeds("layer_maximum", { merge_inputs <- get_merge_inputs() output <- layer_maximum(merge_inputs) keras_model(merge_inputs, output) output <- layer_maximum()(merge_inputs) keras_model(merge_inputs, output) }) test_call_succeeds("layer_minumum", required_version = "2.0.9", { merge_inputs <- get_merge_inputs() output <- layer_minimum(merge_inputs) keras_model(merge_inputs, output) output <- layer_minimum()(merge_inputs) keras_model(merge_inputs, output) }) test_call_succeeds("layer_average", { merge_inputs <- get_merge_inputs() output <- layer_average(merge_inputs) keras_model(merge_inputs, output) output <- layer_average()(merge_inputs) keras_model(merge_inputs, output) }) test_call_succeeds("layer_concatenate", { merge_inputs <- get_merge_inputs() output <- layer_concatenate(merge_inputs) keras_model(merge_inputs, output) output <- layer_concatenate()(merge_inputs) keras_model(merge_inputs, output) }) test_call_succeeds("layer_batch_normalization", { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_batch_normalization() }) test_call_succeeds("layer_gaussian_noise", { skip_if_cntk() keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_gaussian_noise(stddev = 0.5) }) test_call_succeeds("layer_gaussian_dropout", { skip_if_cntk() keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(2,16)) %>% layer_gaussian_dropout(rate = 0.5) }) test_call_succeeds("time_distributed", { keras_model_sequential() %>% time_distributed(layer_dense(units = 8), input_shape = c(10, 16)) }) test_call_succeeds("bidirectional", { keras_model_sequential() %>% bidirectional(layer_lstm(units = 10, return_sequences = TRUE), input_shape = c(5, 10)) %>% bidirectional(layer_lstm(units = 10)) %>% layer_dense(units = 5) %>% layer_activation(activation = "softmax") }) test_call_succeeds("layer_activation_softmax", required_version = "2.1.3", { if (is_tensorflow_implementation()) { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_activation_softmax() } }) test_call_succeeds("layer_separable_conv_1d", required_version = "2.1.3", { if (is_tensorflow_implementation()) { keras_model_sequential() %>% layer_dense(32, input_shape = c(784)) %>% layer_reshape(target_shape = c(4, 8)) %>% layer_separable_conv_1d(filters = 4, kernel_size = c(4)) } }) test_call_succeeds('layer_attention',{ if (is_tensorflow_implementation() && tensorflow::tf_version() >= "1.14"){ input_1 = layer_input(shape=c(4,5)) input_2 = layer_input(shape=c(4,5)) layer_attention(c(input_1,input_2)) } }) test_call_succeeds("layer_dense_features", required_version = "2.1.3", { if (is_tensorflow_implementation() && tensorflow::tf_version() >= "1.14") { # functional style fc <- list(tensorflow::tf$feature_column$numeric_column("mpg")) input <- list(mpg = layer_input(1)) out <- input %>% layer_dense_features(feature_columns = fc) # sequential: needs to pass a list in the begining. feature_layer <- layer_dense_features(feature_columns = fc) model <- keras_model_sequential(list( feature_layer, layer_dense(units = 1) )) model %>% compile(loss = "mae", optimizer = "adam") model %>% fit(x = list(mpg = 1:10), y = 1:10, verbose = 0) } }) test_merge_layers <- function(layer_merge, ...) { test_call_succeeds(deparse(substitute(layer_merge)), { merge_inputs <- get_merge_inputs()[1:2] # supplied as a list to constructor output <- layer_merge(merge_inputs, ...) keras_model(merge_inputs, output) # supplied as individual args to the constructor output <- do.call(layer_merge, c(merge_inputs, ...)) keras_model(merge_inputs, output) # instantiate, then call with a list output <- layer_merge(...)(merge_inputs) keras_model(merge_inputs, output) }) } test_merge_layers(layer_add) test_merge_layers(layer_subtract) test_merge_layers(layer_multiply) test_merge_layers(layer_average) test_merge_layers(layer_maximum) test_merge_layers(layer_minimum) test_merge_layers(layer_concatenate) test_merge_layers(layer_concatenate, axis = 1) test_merge_layers(layer_concatenate, axis = 2) test_merge_layers(layer_concatenate, axis = -1) test_merge_layers(layer_concatenate, axis = -2) test_merge_layers(layer_dot, axes = 2) test_merge_layers(layer_dot, axes = 2, normalize = TRUE)