/* Copyright (c) 2016 PaddlePaddle Authors. All Rights Reserve. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. */ #ifdef PADDLE_WITH_CUDA #include #endif #include #include #include #include "ModelConfig.pb.h" #include "paddle/gserver/layers/DataLayer.h" #include "paddle/math/MathUtils.h" #include "LayerGradUtil.h" #include "paddle/testing/TestUtil.h" using namespace paddle; // NOLINT using namespace std; // NOLINT DECLARE_bool(use_gpu); DECLARE_int32(gpu_id); DECLARE_double(checkgrad_eps); DECLARE_bool(thread_local_rand_use_global_seed); DECLARE_bool(prev_batch_state); TEST(Operator, dot_mul) { TestConfig config; config.layerConfig.set_size(10); config.inputDefs.push_back({INPUT_DATA, "layer_0", 10, 0}); config.inputDefs.push_back({INPUT_DATA, "layer_1", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); OperatorConfig& operatorConf = *config.layerConfig.add_operator_confs(); operatorConf.set_type("dot_mul"); operatorConf.set_dotmul_scale(-1); testOperatorGrad(config, operatorConf, 100, false, false); } TEST(Projection, context) { for (auto contextStart : {-5, -3, -1, 0, 3}) { for (auto contextLength : {1, 2, 5, 7}) { for (auto batchSize : {1, 2, 5, 20, 50}) { for (auto trainablePadding : {false, true}) { LOG(INFO) << " contextStart=" << contextStart << " contextLength=" << contextLength << " batchSize=" << batchSize << " trainablePadding=" << trainablePadding; ProjectionConfig conf; conf.set_type("context"); conf.set_input_size(10); conf.set_context_start(contextStart); conf.set_context_length(contextLength); conf.set_trainable_padding(trainablePadding); conf.set_output_size(conf.context_length() * conf.input_size()); int pad = std::max(0, -conf.context_start()) + std::max(0, conf.context_start() + conf.context_length() - 1); for (auto useGpu : {false, true}) { testProjectionGrad( conf, INPUT_SEQUENCE_DATA, trainablePadding ? conf.input_size() * pad : 0, batchSize, useGpu, contextStart + contextLength <= 1); // = testState } } } } } } TEST(Projection, trans_fc) { ProjectionConfig conf; conf.set_type("trans_fc"); conf.set_input_size(50); conf.set_output_size(20); for (auto useGpu : {false, true}) { testProjectionGrad(conf, INPUT_DATA, /* parameterSize */ 1000, /* batchSize */ 100, useGpu); } } TEST(Projection, fc) { ProjectionConfig conf; conf.set_type("fc"); conf.set_input_size(10); conf.set_output_size(20); for (auto useGpu : {false, true}) { testProjectionGrad(conf, INPUT_DATA, /* parameterSize */ 200, /* batchSize */ 100, useGpu); } } TEST(Projection, dot_mul) { ProjectionConfig conf; conf.set_type("dot_mul"); conf.set_input_size(20); conf.set_output_size(20); for (auto useGpu : {false, true}) { testProjectionGrad(conf, INPUT_DATA, /* parameterSize */ 20, /* batchSize */ 100, useGpu); } } TEST(Projection, table) { ProjectionConfig conf; conf.set_type("table"); conf.set_input_size(10); conf.set_output_size(20); for (auto useGpu : {false, true}) { testProjectionGrad(conf, INPUT_LABEL, /* parameterSize */ 200, /* batchSize */ 100, useGpu); } } TEST(Projection, identity) { ProjectionConfig conf; conf.set_type("identity"); conf.set_input_size(10); conf.set_output_size(10); for (auto useGpu : {false, true}) { testProjectionGrad(conf, INPUT_DATA, /* parameterSize */ 0, /* batchSize */ 100, useGpu); } } TEST(Projection, slice) { ProjectionConfig conf; conf.set_type("slice"); conf.set_input_size(100); SliceConfig& slice1 = *conf.add_slices(); slice1.set_start(10); slice1.set_end(20); SliceConfig& slice2 = *conf.add_slices(); slice2.set_start(50); slice2.set_end(70); conf.set_output_size(30); for (auto useGpu : {false, true}) { testProjectionGrad(conf, INPUT_DATA, /* parameterSize */ 0, /* batchSize */ 10, useGpu); } } TEST(Projection, scaling) { ProjectionConfig conf; conf.set_type("scaling"); conf.set_input_size(10); conf.set_output_size(10); for (auto useGpu : {false}) { testProjectionGrad(conf, INPUT_DATA, /* parameterSize */ 1, /* batchSize */ 100, useGpu); } } void testProjectionConv(size_t groups, bool isDeconv) { const int NUM_FILTERS = 18; const int FILTER_SIZE = 2; const int FILTER_SIZE_Y = 2; const int CHANNELS = 3; const int IMAGE_SIZE = 16; #if CUDNN_VERSION >= 6000 const int DILATION = 2; #else const int DILATION = 1; #endif ProjectionConfig conf; if (isDeconv) { conf.set_type("convt"); } else { conf.set_type("conv"); } conf.set_num_filters(NUM_FILTERS); ConvConfig* conv = conf.mutable_conv_conf(); conv->set_filter_size(FILTER_SIZE); conv->set_filter_size_y(FILTER_SIZE_Y); conv->set_channels(CHANNELS); conv->set_padding(0); conv->set_padding_y(1); conv->set_stride(2); conv->set_stride_y(2); conv->set_dilation(DILATION); conv->set_dilation_y(DILATION); conv->set_groups(groups); if (isDeconv) { conv->set_filter_channels(NUM_FILTERS / conv->groups()); } else { conv->set_filter_channels(conv->channels() / conv->groups()); } conv->set_img_size(IMAGE_SIZE); int output_x = outputSize(conv->img_size(), (conv->filter_size() - 1) * DILATION + 1, conv->padding(), conv->stride(), /* caffeMode */ true); int output_y = outputSize(conv->img_size(), (conv->filter_size_y() - 1) * DILATION + 1, conv->padding_y(), conv->stride_y(), /* caffeMode */ true); conv->set_output_x(output_x); conv->set_output_y(output_y); if (isDeconv) { conf.set_input_size(output_x * output_y * CHANNELS); conf.set_output_size(IMAGE_SIZE * IMAGE_SIZE * NUM_FILTERS); } else { conf.set_input_size(IMAGE_SIZE * IMAGE_SIZE * CHANNELS); conf.set_output_size(output_x * output_y * NUM_FILTERS); } testProjectionGrad(conf, INPUT_DATA, /* parameterSize */ NUM_FILTERS * CHANNELS * FILTER_SIZE * FILTER_SIZE_Y / groups, /* batchSize */ 100, true, false, NUM_FILTERS, true); } #ifdef PADDLE_WITH_CUDA TEST(Projection, conv) { /// test ConvProjection testProjectionConv(1, false); testProjectionConv(3, false); /// test ConvTransProjection testProjectionConv(1, true); testProjectionConv(3, true); } #endif TEST(Layer, BilinearInterpLayer) { TestConfig config; config.layerConfig.set_type("bilinear_interp"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 4096, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); BilinearInterpConfig* bilinear = input->mutable_bilinear_interp_conf(); ImageConfig* image = bilinear->mutable_image_conf(); image->set_img_size(32); image->set_img_size_y(32); image->set_channels(4); for (auto useGpu : {false, true}) { for (auto outSize : {32, 64}) { bilinear->set_out_size_x(outSize); bilinear->set_out_size_y(outSize); testLayerGrad(config, "bilinear_interp", 10, false, useGpu); } } } TEST(Layer, concat) { TestConfig config; config.biasSize = 0; config.layerConfig.set_type("concat"); config.layerConfig.set_size(15); config.layerConfig.set_active_type("sigmoid"); config.inputDefs.push_back({INPUT_DATA, "layer_0", 5, 0}); config.layerConfig.add_inputs(); config.inputDefs.push_back({INPUT_DATA, "layer_1", 10, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "concat", 100, false, useGpu); } } TEST(Layer, AddtoLayer) { TestConfig config; config.biasSize = 0; config.layerConfig.set_type("addto"); config.layerConfig.set_size(10); config.layerConfig.set_active_type("sigmoid"); config.inputDefs.push_back({INPUT_DATA, "layer_0", 10, 0}); config.layerConfig.add_inputs(); config.inputDefs.push_back({INPUT_DATA, "layer_1", 10, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "addto", 100, false, useGpu); } } TEST(Layer, CTCLayer) { TestConfig config; config.layerConfig.set_type("ctc"); config.layerConfig.set_norm_by_times(false); config.layerConfig.set_size(10); config.biasSize = 0; config.inputDefs.push_back({INPUT_SEQUENCE_DATA, "layer_0", 10, 0}); config.inputDefs.push_back({INPUT_SEQUENCE_LABEL, "layer_1", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "ctc", 100, /* trans */ false, /* useGpu */ useGpu); } } TEST(Layer, cosSimLayer) { TestConfig config; config.layerConfig.set_type("cos"); config.layerConfig.set_size(1); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 50, 0}); config.inputDefs.push_back({INPUT_DATA, "layer_1", 50, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "cos", 100, false, useGpu); } } TEST(Layer, CosSimVecMatLayer) { TestConfig config; config.layerConfig.set_type("cos_vm"); config.layerConfig.set_size(5); // output size config.layerConfig.set_cos_scale(2.0); config.inputDefs.push_back({INPUT_DATA, "layer_0", 20, 0}); config.layerConfig.add_inputs(); config.inputDefs.push_back({INPUT_DATA, "layer_1", 100, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "cos_vm", 100, false, useGpu); } } void testDepthwiseConvLayer(const string& type, bool useGpu) { TestConfig config; config.biasSize = 32; config.layerConfig.set_type(type); config.layerConfig.set_num_filters(32); config.layerConfig.set_partial_sum(1); config.layerConfig.set_shared_biases(true); config.inputDefs.push_back({INPUT_DATA, "layer_0", 2048, 192}); LayerInputConfig* input = config.layerConfig.add_inputs(); ConvConfig* conv = input->mutable_conv_conf(); conv->set_filter_size(2); conv->set_filter_size_y(3); conv->set_channels(16); conv->set_padding(0); conv->set_padding_y(1); conv->set_stride(2); conv->set_stride_y(2); conv->set_groups(16); conv->set_filter_channels(conv->channels() / conv->groups()); conv->set_img_size(16); conv->set_img_size_y(8); conv->set_output_x(outputSize(conv->img_size(), conv->filter_size(), conv->padding(), conv->stride(), /* caffeMode */ true)); conv->set_output_y(outputSize(conv->img_size_y(), conv->filter_size_y(), conv->padding_y(), conv->stride_y(), /* caffeMode */ true)); config.layerConfig.set_size(conv->output_x() * conv->output_y() * config.layerConfig.num_filters()); testLayerGrad(config, "depthwise_conv", 100, false, useGpu); // Use small batch_size and useWeight=true to test biasGrad testLayerGrad(config, "depthwise_conv", 2, false, useGpu, true, 0.02); } TEST(Layer, depthwiseConvLayer) { // 'depthwise_conv' is a sepecial case of 'exconv' whose // groups size equals to the input channels size. testDepthwiseConvLayer("exconv", /* useGpu= */ false); #ifdef PADDLE_WITH_CUDA testDepthwiseConvLayer("exconv", /* useGpu= */ true); #endif } void testConvLayer(const string& type, bool trans, bool useGpu) { TestConfig config; config.biasSize = 16; config.layerConfig.set_type(type); config.layerConfig.set_num_filters(16); config.layerConfig.set_partial_sum(1); config.layerConfig.set_shared_biases(true); int dilation = 1; if (type == "cudnn_conv") { #if CUDNN_VERSION >= 6000 dilation = 2; #else dilation = 1; #endif } config.inputDefs.push_back({INPUT_DATA, "layer_0", 768, 192}); LayerInputConfig* input = config.layerConfig.add_inputs(); ConvConfig* conv = input->mutable_conv_conf(); conv->set_filter_size(2); conv->set_filter_size_y(2); conv->set_channels(3); conv->set_padding(0); conv->set_padding_y(1); conv->set_stride(2); conv->set_stride_y(2); conv->set_dilation(dilation); conv->set_dilation_y(dilation); conv->set_groups(1); conv->set_filter_channels(conv->channels() / conv->groups()); conv->set_img_size(16); conv->set_img_size_y(16); conv->set_output_x(outputSize(conv->img_size(), (conv->filter_size() - 1) * dilation + 1, conv->padding(), conv->stride(), /* caffeMode */ true)); conv->set_output_y(outputSize(conv->img_size_y(), (conv->filter_size_y() - 1) * dilation + 1, conv->padding_y(), conv->stride_y(), /* caffeMode */ true)); config.layerConfig.set_size(conv->output_x() * conv->output_y() * config.layerConfig.num_filters()); testLayerGrad(config, "conv", 100, trans, useGpu); // Use small batch_size and useWeight=true to test biasGrad testLayerGrad(config, "conv", 2, trans, useGpu, true, 0.02); } TEST(Layer, convLayer) { testConvLayer("exconv", /* trans= */ false, /* useGpu= */ false); #ifdef PADDLE_WITH_CUDA testConvLayer("exconv", /* trans= */ false, /* useGpu= */ true); testConvLayer("cudnn_conv", /* trans= */ false, /* useGpu= */ true); #endif } void testConvTransLayer(const string& type, bool trans, bool useGpu) { TestConfig config; config.biasSize = 3; config.layerConfig.set_type(type); config.layerConfig.set_num_filters(3); config.layerConfig.set_partial_sum(1); config.layerConfig.set_shared_biases(true); config.inputDefs.push_back({INPUT_DATA, "layer_0", 1024, 384}); LayerInputConfig* input = config.layerConfig.add_inputs(); ConvConfig* conv = input->mutable_conv_conf(); conv->set_filter_size(2); conv->set_filter_size_y(4); conv->set_channels(16); conv->set_padding(0); conv->set_padding_y(1); conv->set_stride(2); conv->set_stride_y(2); conv->set_groups(1); conv->set_filter_channels(3 / conv->groups()); conv->set_img_size(16); conv->set_output_x(outputSize(conv->img_size(), conv->filter_size(), conv->padding(), conv->stride(), /* caffeMode */ true)); config.layerConfig.set_size(conv->img_size() * conv->img_size() * config.layerConfig.num_filters()); testLayerGrad(config, "convTrans", 100, trans, useGpu); // Use small batch_size and useWeight=true to test biasGrad testLayerGrad(config, "convTrans", 2, trans, useGpu, true, 0.02); } TEST(Layer, convTransLayer) { for (auto useGpu : {false, true}) { testConvTransLayer("exconvt", /* trans= */ false, /* useGpu= */ useGpu); } #ifdef PADDLE_WITH_CUDA testConvTransLayer("cudnn_convt", /* trans= */ false, /* useGpu= */ true); #endif } TEST(Layer, blockExpandLayer) { TestConfig config; config.biasSize = 0; config.layerConfig.set_type("blockexpand"); config.inputDefs.push_back({INPUT_DATA, "layer_0", 6144, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); BlockExpandConfig* blockExpand = input->mutable_block_expand_conf(); blockExpand->set_img_size_x(64); blockExpand->set_img_size_y(32); blockExpand->set_channels(3); blockExpand->set_padding_x(0); blockExpand->set_padding_y(0); blockExpand->set_block_x(4); blockExpand->set_block_y(32); blockExpand->set_stride_x(2); blockExpand->set_stride_y(2); blockExpand->set_output_x(outputSize(blockExpand->img_size_x(), blockExpand->block_x(), blockExpand->padding_x(), blockExpand->stride_x(), /* caffeMode */ false)); blockExpand->set_output_y(outputSize(blockExpand->img_size_y(), blockExpand->block_y(), blockExpand->padding_y(), blockExpand->stride_y(), /* caffeMode */ false)); config.layerConfig.set_size(blockExpand->block_x() * blockExpand->block_y() * blockExpand->channels()); for (auto useGpu : {false, true}) { testLayerGrad(config, "blockexpand", 100, false, useGpu); } } TEST(Layer, maxoutLayer) { TestConfig config; config.biasSize = 0; config.layerConfig.set_type("maxout"); config.inputDefs.push_back({INPUT_DATA, "layer_0", 4096, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); MaxOutConfig* maxout = input->mutable_maxout_conf(); ImageConfig* image = maxout->mutable_image_conf(); image->set_img_size(32); image->set_img_size_y(32); image->set_channels(4); maxout->set_groups(2); for (auto useGpu : {false, true}) { testLayerGrad(config, "maxout", 10, false, useGpu); } } void testFcLayer(string format, size_t nnz) { TestConfig config; config.biasSize = 4096; config.layerConfig.set_type("fc"); config.layerConfig.set_size(4096); config.layerConfig.set_active_type("sigmoid"); config.layerConfig.set_drop_rate(0.1); config.inputDefs.push_back( {INPUT_DATA, "layer_0", 8192, nnz, ParaSparse(format)}); config.layerConfig.add_inputs(); LOG(INFO) << config.inputDefs[0].sparse.sparse << " " << config.inputDefs[0].sparse.format; for (auto useGpu : {false, true}) { testLayerGrad(config, "fc", 100, /* trans */ false, useGpu, /* weight */ true); } } TEST(Layer, fcLayer) { testFcLayer("", 4096 * 4096 * 2); testFcLayer("csc", 4096 * 40); testFcLayer("csr", 4096 * 40); } TEST(Layer, SelectiveFullyConnectedLayer) { TestConfig config; size_t nin = 16; size_t nout = 256; config.layerConfig.set_type("selective_fc"); config.layerConfig.set_size(nout); config.layerConfig.set_active_type("sigmoid"); config.layerConfig.set_has_selected_colums(true); config.layerConfig.set_selective_fc_pass_generation(false); config.biasSize = nout; config.inputDefs.push_back({INPUT_DATA, "input0", nin, nin * nout}); config.layerConfig.add_inputs(); config.inputDefs.push_back( {INPUT_SPARSE_NON_VALUE_DATA, "index", nout, 0, ParaSparse("csr", true)}); config.layerConfig.add_inputs(); testLayerGrad(config, "selective_fc", 100, /* trans= */ false, /* useGup= */ false, false); #ifdef PADDLE_WITH_CUDA testLayerGrad(config, "selective_fc", 100, /* trans= */ false, /* useGup= */ true, false); #endif } TEST(Layer, DataNormLayer) { TestConfig config; config.layerConfig.set_type("data_norm"); config.layerConfig.set_size(20); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 20, 100}); config.inputDefs.back().isStatic = true; config.layerConfig.add_inputs(); for (auto strategy : {"z-score", "min-max", "decimal-scaling"}) { config.layerConfig.set_data_norm_strategy(strategy); // The parameters are static, so not support GPU now testLayerGrad(config, "data_norm", 200, /* trans */ false, /* useGpu */ false); } } TEST(Layer, hsigmoidLayer) { TestConfig config; config.layerConfig.set_type("hsigmoid"); config.layerConfig.set_num_classes(5); config.layerConfig.set_size(1); config.biasSize = config.layerConfig.num_classes() - 1; config.inputDefs.push_back({INPUT_DATA, "layer_0", 50, 200}); config.inputDefs.push_back({INPUT_LABEL, "layer_1", 5, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); // Not support GPU now testLayerGrad(config, "hsigmoid", 100, /* trans */ false, /* useGpu */ false); } TEST(Layer, multi_cross) { TestConfig config; config.layerConfig.set_type("multi-class-cross-entropy"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 50, 0}); config.inputDefs.push_back({INPUT_LABEL, "layer_1", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad( config, "multi-class-cross-entropy", 100, /* trans */ false, useGpu); } } TEST(Layer, multi_binary_label_sparse_mat) { TestConfig config; config.layerConfig.set_type("multi_binary_label_cross_entropy"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 50, 0}); config.inputDefs.push_back({INPUT_SPARSE_NON_VALUE_DATA, "layer_1", 50, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "multi_binary_label_cross_entropy", 100, /* trans */ false, useGpu); } } TEST(layer, multi_binary_label_id) { TestConfig config; config.layerConfig.set_type("multi_binary_label_cross_entropy"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 50, 0}); config.inputDefs.push_back({INPUT_LABEL, "layer_1", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "multi_binary_label_cross_entropy", 100, /* trans */ false, useGpu); } } TEST(Layer, multi_cross_with_selfnorm) { TestConfig config; config.layerConfig.set_type("multi_class_cross_entropy_with_selfnorm"); config.layerConfig.set_softmax_selfnorm_alpha(0.1); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 50, 0}); config.inputDefs.push_back({INPUT_LABEL, "layer_1", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); // Not support GPU now testLayerGrad(config, "multi_class_cross_entropy_with_selfnorm", 100, /* trans */ false, /* useGpu */ false); } TEST(Layer, multi_cross_soft) { TestConfig config; config.layerConfig.set_type("soft_binary_class_cross_entropy"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 10, 0}); config.inputDefs.push_back({INPUT_DATA_TARGET, "layer_1", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "soft_binary_class_cross_entropy", 100, /* trans */ false, useGpu); } } TEST(Layer, square_error) { TestConfig config; config.layerConfig.set_type("square_error"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 10, 0}); config.inputDefs.push_back({INPUT_DATA_TARGET, "layer_1", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "square_error", 100, /* trans */ false, useGpu); } } TEST(Layer, sparse_square_error) { TestConfig config; config.layerConfig.set_type("square_error"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 50, 0}); config.inputDefs.push_back({INPUT_SPARSE_NON_VALUE_DATA, "layer_1", 50, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); // "GpuSparseMatrix" as label is not supported testLayerGrad(config, "square_error", 100, /* trans */ false, /* useGpu */ false); } TEST(Layer, sparse_float_square_error) { TestConfig config; config.layerConfig.set_type("square_error"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 50, 0}); config.inputDefs.push_back({INPUT_SPARSE_FLOAT_VALUE_DATA, "layer_1", 50, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); // "GpuSparseMatrix" as label is not supported testLayerGrad(config, "square_error", 100, /* trans */ false, /* useGpu */ false); } TEST(Layer, square_error_weighted) { TestConfig config; config.layerConfig.set_type("square_error"); config.biasSize = 0; config.testAccumulate = false; config.inputDefs.push_back({INPUT_DATA, "layer_0", 10, 0}); config.inputDefs.push_back({INPUT_DATA_TARGET, "layer_1", 10, 0}); config.inputDefs.push_back({INPUT_DATA_TARGET, "layer_2", 1, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "square_error", 100, /* trans */ false, useGpu); } } TEST(Layer, huber_regression_loss) { TestConfig config; config.layerConfig.set_type("huber_regression"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 10, 0}); config.inputDefs.push_back({INPUT_DATA_TARGET, "layer_1", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { for (auto delta : {1, 3, 5}) { config.layerConfig.set_delta(delta); testLayerGrad(config, "huber_regression", 100, /* trans */ false, useGpu); } } } TEST(Layer, huber_two_class) { TestConfig config; config.layerConfig.set_type("huber_classification"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 1, 0}); config.inputDefs.push_back({INPUT_LABEL, "layer_1", 2, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "huber_two_class", 100, /* trans */ false, useGpu); } } void testExpandLayer(string trans_type, bool hasSubseq) { TestConfig config; config.layerConfig.set_type("expand"); config.inputDefs.push_back( {trans_type == "non-seq" ? INPUT_DENSE_DIM_DATA : INPUT_SEQUENCE_DATA, "layer_0", 10, 0}); config.inputDefs.push_back( {hasSubseq ? INPUT_HASSUB_SEQUENCE_DATA : INPUT_SEQUENCE_DATA, "layer_1", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); config.layerConfig.set_trans_type(trans_type); LOG(INFO) << " trans_type=" << trans_type << " hasSubseq=" << hasSubseq; for (auto useGpu : {false, true}) { testLayerGrad(config, "expand", 30, false, useGpu); } } TEST(Layer, ExpandLayer) { testExpandLayer("non-seq", false); // non-seq expand to seq testExpandLayer("non-seq", true); // non-seq expand to hasSubseq testExpandLayer("seq", true); // seq expand to hasSubseq } void testDegradeLayer(bool hasSubseq, string layer_type, string trans_type, int stride) { TestConfig config; config.layerConfig.set_type(layer_type); config.layerConfig.set_size(10); config.layerConfig.set_seq_pool_stride(stride); config.biasSize = 0; config.inputDefs.push_back( {hasSubseq ? INPUT_HASSUB_SEQUENCE_DATA : INPUT_SEQUENCE_DATA, "layer_0", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.set_trans_type(trans_type); auto testDegradeLayerGrad = [](TestConfig& config, string layer_type) { for (auto useGpu : {false, true}) { testLayerGrad(config, layer_type, 100, false, useGpu); } }; if (layer_type == "average") { for (auto strategy : {"average", "sum", "squarerootn"}) { LOG(INFO) << " hasSubseq=" << hasSubseq << " trans_type=" << trans_type << " average_strategy=" << strategy << " seq_pool_stride=" << stride; config.layerConfig.set_average_strategy(strategy); testDegradeLayerGrad(config, layer_type); } } else { LOG(INFO) << " hasSubseq=" << hasSubseq << " trans_type=" << trans_type << " seq_pool_stride=" << stride; testDegradeLayerGrad(config, layer_type); } } TEST(Layer, MaxLayer) { testDegradeLayer(false, "max", "non-seq", -1); // seq max to non-seq testDegradeLayer(false, "max", "non-seq", 5); // seq max to a shorten seq, stride window = 5 testDegradeLayer(true, "max", "non-seq", -1); // hasSubseq max to non-seq testDegradeLayer(true, "max", "seq", -1); // hasSubseq max to seq } TEST(Layer, SequenceLastInstanceLayer) { testDegradeLayer(false, "seqlastins", "non-seq", -1); // seq seqlastins to non-seq testDegradeLayer(false, "seqlastins", "non-seq", 5); // seq seqlastins to a shorten seq, stride window = 5 testDegradeLayer(true, "seqlastins", "non-seq", -1); // hasSubseq seqlastins to non-seq testDegradeLayer( true, "seqlastins", "seq", -1); // hasSubseq seqlastins to seq } TEST(Layer, AverageLayer) { testDegradeLayer(false, "average", "non-seq", -1); // seq average to non-seq testDegradeLayer(false, "average", "non-seq", 5); // seq average to a shorten seq, stride window = 5 testDegradeLayer( true, "average", "non-seq", -1); // hasSubseq average to non-seq testDegradeLayer(true, "average", "seq", -1); // hasSubseq average to seq } TEST(Layer, SequenceConcatLayer) { TestConfig config; config.layerConfig.set_type("seqconcat"); config.layerConfig.set_size(10); config.biasSize = 0; config.inputDefs.push_back({INPUT_SEQUENCE_DATA, "layer_0", 10, 0}); config.layerConfig.add_inputs(); config.inputDefs.push_back({INPUT_SEQUENCE_DATA, "layer_1", 10, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "seqconcat", 100, false, useGpu); } } TEST(Layer, SequenceReshapeLayer) { TestConfig config; config.layerConfig.set_type("seqreshape"); config.layerConfig.set_size(10); config.inputDefs.push_back({INPUT_SEQUENCE_DATA, "layer_0", 100, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "seqreshape", 100, false, useGpu); } } TEST(Layer, ConvShiftLayer) { TestConfig config; config.layerConfig.set_type("conv_shift"); config.layerConfig.set_size(10); config.inputDefs.push_back({INPUT_DATA, "layer_0", 10, 0}); config.inputDefs.push_back({INPUT_DATA, "layer_1", 3, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); // Not support GPU now testLayerGrad(config, "conv_shift", 100, false, false); } TEST(Layer, PowerLayer) { TestConfig config; config.layerConfig.set_type("power"); config.layerConfig.set_size(10); config.inputDefs.push_back({INPUT_DATA, "layer_0", 1, 0}); config.inputDefs.push_back({INPUT_DATA, "layer_1", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "power", 100, false, useGpu); } } TEST(Layer, ConvexCombinationLayer) { TestConfig config; config.layerConfig.set_type("convex_comb"); config.layerConfig.set_size(20); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 5, 0}); config.inputDefs.push_back({INPUT_DATA, "layer_1", 100, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "convex_comb", 100, false, useGpu); } } TEST(Layer, InterpolationLayer) { TestConfig config; config.layerConfig.set_type("interpolation"); config.layerConfig.set_size(10); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 1, 0}); config.inputDefs.push_back({INPUT_DATA, "layer_1", 10, 0}); config.inputDefs.push_back({INPUT_DATA, "layer_2", 10, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "interpolation", 100, false, useGpu); } } TEST(Layer, OuterProdLayer) { TestConfig config; config.layerConfig.set_type("out_prod"); config.layerConfig.set_size(100); config.inputDefs.push_back({INPUT_DATA, "layer_0", 10, 0}); config.layerConfig.add_inputs(); config.inputDefs.push_back({INPUT_DATA, "layer_1", 10, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "out_prod", 100, false, useGpu); } } TEST(Layer, SlopeInterceptLayer) { TestConfig config; config.layerConfig.set_type("slope_intercept"); config.layerConfig.set_size(10); config.layerConfig.set_slope(1.0); config.layerConfig.set_intercept(0.1); config.inputDefs.push_back({INPUT_DATA, "layer_0", 10, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "slope_intercept", 100, false, useGpu); } } TEST(Layer, ScalingLayer) { TestConfig config; config.layerConfig.set_type("scaling"); config.layerConfig.set_size(10); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 1, 0}); config.layerConfig.add_inputs(); config.inputDefs.push_back({INPUT_DATA, "layer_1", 10, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "scaling", 100, false, useGpu); } } void testNormLayer(const string& normType, bool trans, bool useGpu) { TestConfig config; config.layerConfig.set_type("norm"); config.layerConfig.set_active_type("relu"); config.inputDefs.push_back({INPUT_DATA, "layer_0", 1568, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); NormConfig* norm = input->mutable_norm_conf(); norm->set_norm_type(normType); norm->set_channels(16); norm->set_size(5); norm->set_scale(0.001); norm->set_pow(0.75); norm->set_blocked(0); norm->set_img_size(14); norm->set_img_size_y(7); norm->set_output_x(norm->img_size()); norm->set_output_y(norm->img_size_y()); if (norm->norm_type() == "cmrnorm" || norm->norm_type() == "cmrnorm-projection") { norm->set_scale(norm->scale() / norm->size()); } else { norm->set_scale(norm->scale() / (norm->size() * norm->size())); } config.layerConfig.set_size(norm->output_x() * norm->output_y() * norm->channels()); config.biasSize = 0; testLayerGrad(config, "norm", 100, trans, useGpu); } TEST(Layer, NormLayer) { testNormLayer("cmrnorm-projection", /* trans= */ false, /* useGpu= */ true); testNormLayer("cmrnorm-projection", /* trans= */ false, /* useGpu= */ false); } void setPoolConfig(TestConfig* config, PoolConfig* pool, const string& poolType) { (*config).biasSize = 0; (*config).layerConfig.set_type("pool"); (*config).layerConfig.set_num_filters(16); int kw = 3, kh = 3; int pw = 0, ph = 0; int sw = 2, sh = 2; pool->set_pool_type(poolType); pool->set_channels(16); pool->set_size_x(kw); pool->set_size_y(kh); pool->set_start(0); pool->set_padding(pw); pool->set_padding_y(ph); pool->set_stride(sw); pool->set_stride_y(sh); int ow = outputSize(pool->img_size(), kw, pw, sw, /* caffeMode */ false); int oh = outputSize(pool->img_size_y(), kh, ph, sh, /* caffeMode */ false); pool->set_output_x(ow); pool->set_output_y(oh); } void testPoolLayer(const string& poolType, bool trans, bool useGpu) { TestConfig config; config.inputDefs.push_back({INPUT_DATA, "layer_0", 3136, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); PoolConfig* pool = input->mutable_pool_conf(); pool->set_img_size(14); pool->set_img_size_y(14); setPoolConfig(&config, pool, poolType); config.layerConfig.set_size(pool->output_x() * pool->output_y() * pool->channels()); testLayerGrad(config, "pool", 100, trans, useGpu); } #ifdef PADDLE_WITH_CUDA void testPoolLayer2(const string& poolType, bool trans, bool useGpu) { TestConfig config; config.inputDefs.push_back({INPUT_DATA, "layer_0", 3200, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); PoolConfig* pool = input->mutable_pool_conf(); pool->set_size_y(4); pool->set_stride_y(3); pool->set_img_size(10); pool->set_img_size_y(20); setPoolConfig(&config, pool, poolType); pool->set_output_y((pool->img_size_y() - pool->start() - pool->size_y()) / ((float)pool->stride_y()) + 1.5); config.layerConfig.set_size(pool->output_x() * pool->output_y() * pool->channels()); testLayerGrad(config, "pool", 100, trans, useGpu); } #endif TEST(Layer, PoolLayer) { testPoolLayer("avg-projection", /* trans= */ false, /* useGpu= */ false); testPoolLayer("max-projection", /* trans= */ false, /* useGpu= */ false); #ifdef PADDLE_WITH_CUDA testPoolLayer("avg-projection", /* trans= */ false, /* useGpu= */ true); testPoolLayer("max-projection", /* trans= */ false, /* useGpu= */ true); testPoolLayer("cudnn-max-pool", /* trans= */ false, /* useGpu= */ true); testPoolLayer("cudnn-avg-pool", /* trans= */ false, /* useGpu= */ true); testPoolLayer2("cudnn-max-pool", /* trans= */ false, /* useGpu= */ true); testPoolLayer2("cudnn-avg-pool", /* trans= */ false, /* useGpu= */ true); #endif } void setPool3DConfig(TestConfig* config, PoolConfig* pool, const string& poolType) { // filter size const int NUM_FILTERS = 16; const int FILTER_SIZE = 3; const int FILTER_SIZE_Y = 3; const int FILTER_SIZE_Z = 3; const int CHANNELS = 16; (*config).biasSize = 0; (*config).layerConfig.set_type("pool3d"); (*config).layerConfig.set_num_filters(NUM_FILTERS); int kw = FILTER_SIZE, kh = FILTER_SIZE_Y, kd = FILTER_SIZE_Z; int pw = 0, ph = 0, pd = 0; int sw = 2, sh = 2, sd = 2; pool->set_pool_type(poolType); pool->set_pool_type("avg"); pool->set_channels(CHANNELS); pool->set_size_x(kw); pool->set_size_y(kh); pool->set_size_z(kd); pool->set_padding(0); pool->set_padding_y(0); pool->set_padding_z(0); pool->set_stride(sw); pool->set_stride_y(sh); pool->set_stride_z(sd); pool->set_start(0); int ow = outputSize(pool->img_size(), kw, pw, sw, /* caffeMode */ false); int oh = outputSize(pool->img_size_y(), kh, ph, sh, /* caffeMode */ false); int od = outputSize(pool->img_size_z(), kd, pd, sd, /* caffeMode */ false); pool->set_output_x(ow); pool->set_output_y(oh); pool->set_output_z(od); } void testPool3DLayer(const string& poolType, bool trans, bool useGpu) { TestConfig config; config.inputDefs.push_back({INPUT_DATA, "layer_0", 11664, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); PoolConfig* pool = input->mutable_pool_conf(); const int IMAGE_SIZE = 9; const int IMAGE_SIZE_Y = 9; const int IMAGE_SIZE_Z = 9; pool->set_img_size(IMAGE_SIZE); pool->set_img_size_y(IMAGE_SIZE_Y); pool->set_img_size_z(IMAGE_SIZE_Z); setPool3DConfig(&config, pool, poolType); config.layerConfig.set_size(pool->output_x() * pool->output_y() * pool->channels()); testLayerGrad(config, "pool3d", 100, trans, useGpu); } TEST(Layer, Pool3DLayer) { testPool3DLayer("avg", /* trans= */ false, /* useGpu= */ false); testPool3DLayer("max", /* trans= */ false, /* useGpu= */ false); #ifdef PADDLE_WITH_CUDA testPool3DLayer("avg", /* trans= */ false, /* useGpu= */ true); testPool3DLayer("max", /* trans= */ false, /* useGpu= */ true); #endif } void testSppLayer(const string& poolType, const int pyramidHeight, bool trans, bool useGpu) { TestConfig config; config.layerConfig.set_type("spp"); config.inputDefs.push_back({INPUT_DATA, "layer_0", 3200, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); SppConfig* sppConfig = input->mutable_spp_conf(); sppConfig->set_pool_type(poolType); sppConfig->set_pyramid_height(pyramidHeight); ImageConfig* imageConfig = sppConfig->mutable_image_conf(); imageConfig->set_channels(16); imageConfig->set_img_size(10); imageConfig->set_img_size_y(20); int outputSize = (std::pow(4, sppConfig->pyramid_height()) - 1) / (4 - 1); config.layerConfig.set_size(outputSize * imageConfig->channels()); testLayerGrad(config, "spp", 100, trans, useGpu); } TEST(Layer, SpatialPyramidPoolLayer) { for (auto useGpu : {false, true}) { for (auto pyramidHeight : {1, 2, 3}) { testSppLayer("avg-projection", pyramidHeight, false, useGpu); testSppLayer("max-projection", pyramidHeight, false, useGpu); } } } TEST(Layer, rankCostLayer) { TestConfig config; config.layerConfig.set_type("rank-cost"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 1, 0}); config.inputDefs.push_back({INPUT_DATA, "layer_1", 1, 0}); config.inputDefs.push_back({INPUT_DATA_TARGET, "layer_2", 1, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "rank-cost", 100, false, useGpu); } } TEST(Layer, sumCostLayer) { TestConfig config; config.layerConfig.set_type("sum_cost"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 1, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "sum_cost", 100, false, useGpu); } } TEST(Layer, weightedRankCostLayer) { TestConfig config; config.layerConfig.set_type("rank-cost"); config.biasSize = 0; config.inputDefs.push_back({INPUT_DATA, "layer_0", 1, 0}); config.inputDefs.push_back({INPUT_DATA, "layer_1", 1, 0}); config.inputDefs.push_back({INPUT_DATA_TARGET, "layer_2", 1, 0}); config.inputDefs.push_back({INPUT_DATA_TARGET, "layer_3", 1, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "weighted-rank-cost", 100, false, useGpu); } } TEST(Layer, TensorLayer) { TestConfig config; config.layerConfig.set_type("tensor"); config.layerConfig.set_size(10); config.layerConfig.set_active_type("sigmoid"); config.biasSize = config.layerConfig.size(); config.inputDefs.push_back({INPUT_DATA, "layer_0", 5, 250}); config.inputDefs.push_back({INPUT_DATA, "layer_1", 5, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "tensor", 100, false, useGpu); } } TEST(Layer, RecurrentLayer) { TestConfig config; config.layerConfig.set_type("recurrent"); config.layerConfig.set_size(4); config.layerConfig.set_active_type("tanh"); config.biasSize = 4; config.inputDefs.push_back( {INPUT_SEQUENCE_DATA, "layer_0", /* dim= */ 4, /* paraSize= */ 16}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { for (auto reversed : {false, true}) { config.layerConfig.set_reversed(reversed); config.testState = !reversed; testLayerGrad(config, "recurrent", 50, /* trans= */ false, useGpu); } } } TEST(Layer, LstmLayer) { TestConfig config; config.layerConfig.set_type("lstmemory"); config.layerConfig.set_size(4); config.layerConfig.set_active_type("tanh"); config.layerConfig.set_active_state_type("sigmoid"); config.layerConfig.set_active_gate_type("sigmoid"); config.biasSize = 28; config.inputDefs.push_back( {INPUT_SEQUENCE_DATA, "layer_0", /* dim= */ 16, /* paraSize= */ 64}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { for (auto reversed : {false, true}) { config.layerConfig.set_reversed(reversed); config.testState = !reversed; testLayerGrad(config, "lstmemory", 100, /* trans= */ false, useGpu); } } for (auto useGpu : {true}) { config.testBatchState = true; config.layerConfig.set_reversed(false); testLayerGrad(config, "lstmemory", 10, /* trans= */ false, useGpu); } } TEST(Layer, MDLstmLayer) { TestConfig config; config.layerConfig.set_type("mdlstmemory"); config.layerConfig.set_size(4); config.layerConfig.set_active_type("sigmoid"); config.layerConfig.set_active_state_type("sigmoid"); config.layerConfig.set_active_gate_type("sigmoid"); config.biasSize = 4 * 9; config.inputDefs.push_back( {INPUT_SEQUENCE_MDIM_DATA, "layer_0", 4 * 5, 4 * 4 * 5}); config.layerConfig.add_inputs(); config.layerConfig.add_directions(true); config.layerConfig.add_directions(true); for (auto useGpu : {false, true}) { for (int i = 0; i < 2; i++) { for (int j = 0; j < 2; j++) { config.layerConfig.set_directions(0, bool(i)); config.layerConfig.set_directions(1, bool(j)); testLayerGrad(config, "mdlstmemory", 100, false, useGpu); } } } } TEST(Layer, ParameterReluLayer) { auto testParameterReluLayer = [&](size_t inputSize, size_t channels) { TestConfig config; config.layerConfig.set_type("prelu"); config.inputDefs.push_back({INPUT_DATA, "layer_0", inputSize, channels}); config.layerConfig.add_inputs(); config.layerConfig.set_size(inputSize); config.layerConfig.set_partial_sum(inputSize / channels); // size of feature map for (auto useGpu : {false, true}) { testLayerGrad(config, "prelu", 100, false, useGpu); } }; testParameterReluLayer(192, 1); testParameterReluLayer(192, 3); testParameterReluLayer(192, 192); } TEST(Layer, ResizeLayer) { TestConfig config; config.biasSize = 0; config.layerConfig.set_type("resize"); config.layerConfig.set_size(64); config.inputDefs.push_back({INPUT_DATA, "layer_0", 16, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "resize", 100, false, useGpu); } } TEST(Layer, RotateLayer) { TestConfig config; config.biasSize = 0; config.layerConfig.set_type("rotate"); const int CHANNEL = 2; const int HEIGHT = 8; const int WIDTH = 4; const int INPUT_SIZE = HEIGHT * WIDTH * CHANNEL; config.layerConfig.set_size(INPUT_SIZE); config.layerConfig.set_height(HEIGHT); config.layerConfig.set_width(WIDTH); config.inputDefs.push_back({INPUT_DATA, "layer_0", INPUT_SIZE, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "rotate", 100, false, useGpu); } } TEST(Layer, NCELayer) { TestConfig config; size_t numClasses = 4; config.layerConfig.set_type("nce"); config.layerConfig.set_size(1); config.layerConfig.set_active_type("sigmoid"); config.layerConfig.set_num_classes(numClasses); config.biasSize = numClasses; config.inputDefs.push_back( {INPUT_DATA, "layer_0", /* dim= */ 16, /* paraSize= */ 16 * numClasses}); config.inputDefs.push_back( {INPUT_LABEL, "label", /* dim= */ numClasses, /* paraSize= */ 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto withWeight : {false, true}) { if (withWeight) { config.inputDefs.push_back( {INPUT_DATA_TARGET, "weight", /* dim= */ 1, /* paraSize= */ 0}); config.layerConfig.add_inputs(); } for (auto isIdLabel : {false, true}) { config.inputDefs[1] = { isIdLabel ? INPUT_LABEL : INPUT_SPARSE_NON_VALUE_DATA, "label", /* dim= */ numClasses, /* paraSize= */ 0}; for (auto withDist : {false, true}) { config.layerConfig.clear_neg_sampling_dist(); if (withDist) { double sum = 0; for (size_t i = 0; i < numClasses; ++i) { real p = rand(); // NOLINT use rand_r config.layerConfig.add_neg_sampling_dist(p); sum += p; } for (size_t i = 0; i < numClasses; ++i) { real p = config.layerConfig.neg_sampling_dist(i) / sum; config.layerConfig.set_neg_sampling_dist(i, p); } } LOG(INFO) << "NCELayer " << " isIdLabel=" << isIdLabel << " withWeight=" << withWeight << " withDist=" << withDist; // Not support GPU now testLayerGrad(config, "nce", 100, /* trans= */ false, /* useGpu */ false); } } } } TEST(Layer, GatedRecurrentLayer) { TestConfig config; config.layerConfig.set_type("gated_recurrent"); config.layerConfig.set_size(4); config.layerConfig.set_active_type("sigmoid"); config.layerConfig.set_active_gate_type("sigmoid"); config.biasSize = 12; config.inputDefs.push_back( {INPUT_SEQUENCE_DATA, "layer_0", /* dim= */ 12, /* paraSize= */ 48}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { for (auto reversed : {false, true}) { config.layerConfig.set_reversed(reversed); config.testState = !reversed; testLayerGrad(config, "gated_recurrent", 100, /* trans= */ false, useGpu); } } } TEST(Layer, GruStepLayer) { TestConfig config; config.layerConfig.set_type("gru_step"); config.layerConfig.set_size(4); config.layerConfig.set_active_type("sigmoid"); config.layerConfig.set_active_gate_type("sigmoid"); config.biasSize = 12; config.inputDefs.push_back( {INPUT_DATA, "layer_0", /* dim= */ 12, /* paraSize= */ 48}); config.inputDefs.push_back( {INPUT_DATA, "layer_1", /* dim= */ 4, /* paraSize= */ 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "gruStep", 100, /* trans= */ false, useGpu); } } TEST(Layer, LstmStepLayer) { TestConfig config; config.layerConfig.set_type("lstm_step"); config.layerConfig.set_size(4); config.layerConfig.set_active_type("sigmoid"); config.layerConfig.set_active_state_type("sigmoid"); config.layerConfig.set_active_gate_type("sigmoid"); config.biasSize = 12; config.testAccumulate = false; config.inputDefs.push_back( {INPUT_DATA, "layer_0", /* dim= */ 16, /* paraSize= */ 0}); config.inputDefs.push_back( {INPUT_DATA, "layer_1", /* dim= */ 4, /* paraSize= */ 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "lstmStep", 100, /* trans= */ false, useGpu); } } void testBatchNormLayer(const string& type, bool trans, bool useGpu) { TestConfig config; const int CHANNELS = 10; const int IMG_SIZE = 16; const int IMG_SIZE_Y = 8; size_t size = CHANNELS * IMG_SIZE * IMG_SIZE_Y; config.layerConfig.set_type(type); config.layerConfig.set_size(size); config.layerConfig.set_active_type("sigmoid"); config.biasSize = CHANNELS; config.inputDefs.push_back({INPUT_DATA, "layer_0", /* dim= */ size, /* paraSize= */ CHANNELS}); config.inputDefs.push_back({INPUT_DATA, "layer_1_running_mean", 1, CHANNELS}); config.inputDefs.back().isStatic = true; config.inputDefs.push_back({INPUT_DATA, "layer_2_running_var", 1, CHANNELS}); config.inputDefs.back().isStatic = true; LayerInputConfig* input = config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); ImageConfig* img_conf = input->mutable_image_conf(); img_conf->set_channels(CHANNELS); img_conf->set_img_size(IMG_SIZE); img_conf->set_img_size_y(IMG_SIZE_Y); testLayerGrad(config, "batch_norm", 64, /* trans= */ trans, useGpu, /* useWeight */ true); } TEST(Layer, BatchNormalizationLayer) { testBatchNormLayer("batch_norm", false, false); #ifdef PADDLE_WITH_CUDA testBatchNormLayer("batch_norm", false, true); if (hl_get_cudnn_lib_version() >= int(4000)) { testBatchNormLayer("cudnn_batch_norm", false, true); } #endif } void testBatchNorm3DLayer(const string& type, bool trans, bool useGpu) { TestConfig config; const int CHANNELS = 10; const int IMG_SIZE = 16; const int IMG_SIZE_Y = 8; const int IMG_SIZE_Z = 8; size_t size = CHANNELS * IMG_SIZE * IMG_SIZE_Y * IMG_SIZE_Z; config.layerConfig.set_type(type); config.layerConfig.set_size(size); config.layerConfig.set_active_type("sigmoid"); config.biasSize = CHANNELS; config.inputDefs.push_back({INPUT_DATA, "layer_0", /* dim= */ size, /* paraSize= */ CHANNELS}); config.inputDefs.push_back({INPUT_DATA, "layer_1_running_mean", 1, CHANNELS}); config.inputDefs.back().isStatic = true; config.inputDefs.push_back({INPUT_DATA, "layer_2_running_var", 1, CHANNELS}); config.inputDefs.back().isStatic = true; LayerInputConfig* input = config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); ImageConfig* img_conf = input->mutable_image_conf(); img_conf->set_channels(CHANNELS); img_conf->set_img_size(IMG_SIZE); img_conf->set_img_size_y(IMG_SIZE_Y); img_conf->set_img_size_z(IMG_SIZE_Z); testLayerGrad(config, "batch_norm", 64, /* trans= */ trans, useGpu, /* useWeight */ true); } TEST(Layer, testBatchNorm3DLayer) { testBatchNorm3DLayer("batch_norm", false, false); #ifdef PADDLE_WITH_CUDA testBatchNorm3DLayer("batch_norm", false, true); if (hl_get_cudnn_lib_version() >= int(4000)) { testBatchNorm3DLayer("cudnn_batch_norm", false, true); } #endif } void testConvOperator(bool isDeconv) { TestConfig config; const int NUM_FILTERS = 16; const int FILTER_SIZE = 2; const int FILTER_SIZE_Y = 3; const int CHANNELS = 3; const int IMAGE_SIZE = 16; const int IMAGE_SIZE_Y = 9; OperatorConfig& operatorConf = *config.layerConfig.add_operator_confs(); if (isDeconv) { operatorConf.set_type("convt"); } else { operatorConf.set_type("conv"); } ConvConfig* conv = operatorConf.mutable_conv_conf(); operatorConf.set_num_filters(NUM_FILTERS); conv->set_filter_size(FILTER_SIZE); conv->set_filter_size_y(FILTER_SIZE_Y); conv->set_channels(CHANNELS); conv->set_padding(0); conv->set_padding_y(1); conv->set_stride(2); conv->set_stride_y(2); conv->set_groups(1); conv->set_img_size(IMAGE_SIZE); conv->set_img_size_y(IMAGE_SIZE_Y); conv->set_output_x(outputSize(conv->img_size(), conv->filter_size(), conv->padding(), conv->stride(), /* caffeMode */ true)); conv->set_output_y(outputSize(conv->img_size_y(), conv->filter_size_y(), conv->padding_y(), conv->stride_y(), /* caffeMode */ true)); if (isDeconv) { conv->set_filter_channels(NUM_FILTERS / conv->groups()); config.inputDefs.push_back({INPUT_DATA, "layer_0", conv->output_x() * conv->output_y() * CHANNELS, 0}); config.layerConfig.set_size(IMAGE_SIZE * IMAGE_SIZE_Y * NUM_FILTERS); } else { conv->set_filter_channels(conv->channels() / conv->groups()); config.inputDefs.push_back( {INPUT_DATA, "layer_0", IMAGE_SIZE * IMAGE_SIZE_Y * CHANNELS, 0}); config.layerConfig.set_size(conv->output_x() * conv->output_y() * NUM_FILTERS); } config.inputDefs.push_back( {INPUT_DATA, "layer_1", FILTER_SIZE * FILTER_SIZE_Y * CHANNELS * NUM_FILTERS, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); testOperatorGrad(config, operatorConf, 100, /*useGpu*/ true, false); } TEST(Operator, conv) { testConvOperator(/*isDeconv*/ true); testConvOperator(/*isDeconv*/ false); } TEST(Layer, FeatureMapExpandLayer) { TestConfig config; config.layerConfig.set_type("featmap_expand"); const int CHANNELS = 10; const int INPUT_SIZE = 100; config.layerConfig.set_size(INPUT_SIZE * CHANNELS); config.layerConfig.set_num_filters(CHANNELS); config.inputDefs.push_back({INPUT_SEQUENCE_DATA, "layer_0", /* dim= */ INPUT_SIZE, /* paraSize= */ 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { for (auto asRowVec : {false, true}) { config.layerConfig.set_user_arg(asRowVec ? "as_row_vec" : "as_col_vec"); testLayerGrad(config, "featmap_expand", /*batch_size*/ 100, /* trans= */ false, useGpu, /* useWeight */ true); } } } TEST(Layer, MultiplexLayer) { TestConfig config; const int LAYER_SIZE = 100; config.layerConfig.set_type("multiplex"); config.layerConfig.set_size(LAYER_SIZE); config.inputDefs.push_back({INPUT_LABEL, "layer_0", 2, 0}); config.inputDefs.push_back( {INPUT_DATA, "layer_1", /* dim= */ LAYER_SIZE, /* paraSize= */ 0}); config.inputDefs.push_back( {INPUT_DATA, "layer_2", /* dim= */ LAYER_SIZE, /* paraSize= */ 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "multiplex", 512, /* trans= */ false, useGpu); } } TEST(Layer, PadLayer) { TestConfig config; config.biasSize = 0; config.layerConfig.set_type("pad"); int c = 4; int h = 31; int w = 36; size_t size = c * h * w; config.inputDefs.push_back({INPUT_DATA, "layer_0", size, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); PadConfig* pad = input->mutable_pad_conf(); ImageConfig* image = pad->mutable_image_conf(); image->set_channels(c); image->set_img_size(h); image->set_img_size_y(w); pad->add_pad_c(1); pad->add_pad_c(2); pad->add_pad_h(2); pad->add_pad_h(3); pad->add_pad_w(3); pad->add_pad_w(5); for (auto useGpu : {false, true}) { testLayerGrad(config, "pad", 10, false, useGpu); } } TEST(Layer, CrossChannelNormLayer) { TestConfig config; config.paramInitialMean = 1.; config.paramInitialStd = 0.; config.layerConfig.set_type("norm"); config.layerConfig.set_size(100); LayerInputConfig* input = config.layerConfig.add_inputs(); NormConfig* norm = input->mutable_norm_conf(); norm->set_norm_type("cross-channel-norm"); norm->set_channels(10); norm->set_size(100); norm->set_scale(0); norm->set_pow(0); norm->set_blocked(0); config.inputDefs.push_back({INPUT_DATA, "layer_0", 100, 10}); for (auto useGpu : {false, true}) { testLayerGrad(config, "cross-channel-norm", 10, false, useGpu, false); } } TEST(Layer, smooth_l1) { TestConfig config; config.layerConfig.set_type("smooth_l1"); config.inputDefs.push_back({INPUT_DATA, "layer_0", 200, 0}); config.inputDefs.push_back({INPUT_DATA_TARGET, "layer_1", 200, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "smooth_l1", 100, false, useGpu, false); } } TEST(Layer, multibox_loss) { TestConfig config; config.layerConfig.set_type("multibox_loss"); config.biasSize = 0; LayerInputConfig* input = config.layerConfig.add_inputs(); MultiBoxLossConfig* multiboxLoss = input->mutable_multibox_loss_conf(); multiboxLoss->set_num_classes(21); multiboxLoss->set_input_num(1); multiboxLoss->set_overlap_threshold(0.5); multiboxLoss->set_neg_pos_ratio(3); multiboxLoss->set_neg_overlap(0.5); multiboxLoss->set_background_id(0); multiboxLoss->set_height(3); multiboxLoss->set_width(3); size_t gtNum = 1; MatrixPtr labelValue = Matrix::create(gtNum, 6, false, false); labelValue->randomizeUniform(); labelValue->add(-0.5); labelValue->sigmoid(*labelValue); real* labelData = labelValue->getData(); size_t labelWidth = labelValue->getWidth(); for (size_t i = 0; i < gtNum; ++i) { *(labelData + i * labelWidth) = std::rand() % 20 + 1; *(labelData + i * labelWidth + 1) = 0.400259; *(labelData + i * labelWidth + 2) = 0.377857; *(labelData + i * labelWidth + 3) = 0.525712; *(labelData + i * labelWidth + 4) = 0.519368; } vector seqStartPositions(gtNum + 1, 0); for (size_t i = 1; i <= gtNum; ++i) { seqStartPositions[i] = i; } // Ensure at lease one matched bbox MatrixPtr priorValue = Matrix::create(1, 72, false, false); priorValue->randomizeUniform(); priorValue->add(-0.5); priorValue->sigmoid(*priorValue); real* priorData = priorValue->getData(); *(priorData) = 0.424811; *(priorData + 1) = 0.397059; *(priorData + 2) = 0.538905; *(priorData + 3) = 0.447091; *(priorData + 4) = 0.425720; *(priorData + 5) = 0.515228; *(priorData + 6) = 0.519452; *(priorData + 7) = 0.591065; config.inputDefs.push_back( {INPUT_SELF_DEFINE_DATA, "priorbox", priorValue, {}}); config.inputDefs.push_back( {INPUT_SELF_DEFINE_DATA, "label", labelValue, seqStartPositions}); config.inputDefs.push_back({INPUT_DATA, "locPred", 36, 0}); config.inputDefs.push_back({INPUT_DATA, "confPred", 189, 0}); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "multibox_loss", 1, false, useGpu, false); } } TEST(Layer, TransLayer) { TestConfig config; const int height = 128; const int width = 1028; config.layerConfig.set_type("trans"); config.layerConfig.set_size(width); config.inputDefs.push_back( {INPUT_DATA, "layer_0", /* dim= */ height * width, /* paraSize= */ 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "trans", height, /* trans= */ false, useGpu); } } TEST(Layer, RowConvLayer) { const int context = 3; const int size = 512; TestConfig config; config.layerConfig.set_type("row_conv"); config.layerConfig.set_size(size); config.layerConfig.set_active_type("sigmoid"); config.inputDefs.push_back( {INPUT_SEQUENCE_DATA, "layer_0", size, context * size}); LayerInputConfig* input = config.layerConfig.add_inputs(); RowConvConfig* conv = input->mutable_row_conv_conf(); conv->set_context_length(context); for (auto useGpu : {false, true}) { testLayerGrad(config, "row_conv", 100, false, useGpu, false); } } TEST(Layer, CropLayer) { TestConfig config; // config input_0 config.inputDefs.push_back({INPUT_DATA, "layer_0", 1024, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); ImageConfig* img = input->mutable_image_conf(); img->set_channels(4); img->set_img_size(16); config.layerConfig.set_axis(2); config.layerConfig.add_offset(0); config.layerConfig.add_offset(0); // config input_1 config.inputDefs.push_back({INPUT_DATA, "layer_1", 128, 0}); input = config.layerConfig.add_inputs(); img = input->mutable_image_conf(); img->set_channels(2); img->set_img_size(8); // config crop layer config.layerConfig.set_type("crop"); config.layerConfig.set_name("cropLayer"); for (auto useGpu : {false, true}) { testLayerGrad(config, "crop", 100, false, useGpu, false); } } TEST(Layer, SwitchOrderLayer) { TestConfig config; // config input_0 config.inputDefs.push_back({INPUT_DATA, "layer_0", 1024, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); ImageConfig* img = input->mutable_image_conf(); img->set_channels(4); img->set_img_size(16); img->set_img_size_y(16); ReshapeConfig* reshape = config.layerConfig.mutable_reshape_conf(); reshape->add_height_axis(0); reshape->add_height_axis(1); reshape->add_height_axis(2); reshape->add_width_axis(3); // config softmax layer config.layerConfig.set_type("switch_order"); config.layerConfig.set_name("switchOrderLayer"); for (auto useGpu : {false, true}) { testLayerGrad(config, "switch_order", 100, false, useGpu, true); } } vector randSampling(real range, int n) { CHECK_GE(range, n); vector num(range); iota(begin(num), end(num), 0.); if (range == n) return num; random_shuffle(begin(num), end(num)); num.resize(n); sort(begin(num), end(num)); return num; } TEST(Layer, SubNestedSequenceLayer) { // layer size is not crutial for this layer, // so use a small layer size in unittest const int layerSize = 4; const int maxSeqNum = 50; const int maxSeqLen = 50; const int maxBeamSize = 32; srand((size_t)(time(NULL))); int beamSize = 1 + (rand() % maxBeamSize); TestConfig config; config.layerConfig.set_type("sub_nested_seq"); config.layerConfig.set_name("sub_nested_seq_layer"); config.layerConfig.set_size(layerSize); int seqNum = 1 + (rand() % maxSeqNum); // sequence information for the first input, it is a nested sequence vector seqStartPos(seqNum + 1, 0); vector subSeqStartPos(1, 0); // selected indices MatrixPtr selectedIndices = Matrix::create(seqNum, beamSize, false, false); selectedIndices->one(); selectedIndices->mulScalar(-1.); real* indicesData = selectedIndices->getData(); for (int i = 0; i < seqNum; ++i) { int subSeqNum = 1 + (rand() % maxSeqNum); for (int j = 0; j < subSeqNum; ++j) { subSeqStartPos.push_back(subSeqStartPos.back() + (1 + (rand() % maxSeqLen))); } vector selSeqs = randSampling(static_cast(subSeqNum), min(beamSize, subSeqNum)); memcpy(indicesData + (i * beamSize), selSeqs.data(), selSeqs.size() * sizeof(real)); seqStartPos[i + 1] = subSeqStartPos.back(); } MatrixPtr seqInputPtr = Matrix::create(seqStartPos.back(), layerSize, false, false); seqInputPtr->randomizeUniform(); config.inputDefs.push_back({INPUT_SELF_DEFINE_DATA, "nested_seq_input", seqInputPtr, seqStartPos, subSeqStartPos}); config.layerConfig.add_inputs(); config.inputDefs.push_back( {INPUT_SELF_DEFINE_DATA, "selected_indices", selectedIndices}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "sub_nested_seq", /* batchSize */ seqNum, /* trans */ false, /* useGpu*/ useGpu, /* useWeight */ false); } } TEST(Layer, ClipLayer) { const size_t batchSize = 128; const size_t size = 512; TestConfig config; config.layerConfig.set_type("clip"); config.inputDefs.push_back({INPUT_DATA, "input", size, 0}); LayerInputConfig* input = config.layerConfig.add_inputs(); ClipConfig* layerConf = input->mutable_clip_conf(); double p1 = std::rand() / (double)RAND_MAX; double p2 = std::rand() / (double)RAND_MAX; layerConf->set_min(std::min(p1, p2)); layerConf->set_max(std::max(p1, p2)); for (auto useGpu : {false, true}) { testLayerGrad(config, "clip", batchSize, false, useGpu, false); } } TEST(Layer, RowL2NormLayer) { const size_t batchSize = 128; const size_t size = 512; TestConfig config; config.layerConfig.set_type("row_l2_norm"); config.layerConfig.set_size(size); config.inputDefs.push_back({INPUT_DATA, "input", size, 0}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "row_l2_norm", batchSize, false, useGpu, false); } } void test3DConvLayer(const string& type, bool trans, bool useGpu) { // filter size const int NUM_FILTERS = 6; // const int CHANNELS = 3; const int FILTER_SIZE = 3; const int FILTER_SIZE_Y = 3; const int FILTER_SIZE_Z = 3; // input image const int CHANNELS = 3; const int IMAGE_SIZE = 9; const int IMAGE_SIZE_Y = 9; const int IMAGE_SIZE_Z = 9; TestConfig config; config.biasSize = NUM_FILTERS; config.layerConfig.set_type(type); config.layerConfig.set_num_filters(NUM_FILTERS); config.layerConfig.set_partial_sum(1); config.layerConfig.set_shared_biases(true); // Setting up conv3D-trans layer LayerInputConfig* input = config.layerConfig.add_inputs(); ConvConfig* conv = input->mutable_conv_conf(); conv->set_channels(CHANNELS); conv->set_filter_size(FILTER_SIZE); conv->set_filter_size_y(FILTER_SIZE_Y); conv->set_filter_size_z(FILTER_SIZE_Z); conv->set_padding(0); conv->set_padding_y(0); conv->set_padding_z(0); conv->set_stride(2); conv->set_stride_y(2); conv->set_stride_z(2); conv->set_img_size(IMAGE_SIZE); conv->set_img_size_y(IMAGE_SIZE_Y); conv->set_img_size_z(IMAGE_SIZE_Z); conv->set_output_x(outputSize(conv->img_size(), conv->filter_size(), conv->padding(), conv->stride(), /* caffeMode */ true)); conv->set_output_y(outputSize(conv->img_size_y(), conv->filter_size_y(), conv->padding_y(), conv->stride_y(), /* caffeMode */ true)); conv->set_output_z(outputSize(conv->img_size_z(), conv->filter_size_z(), conv->padding_z(), conv->stride_z(), /* caffeMode */ true)); config.layerConfig.set_size(conv->output_x() * conv->output_y() * conv->output_z() * NUM_FILTERS); conv->set_groups(1); conv->set_filter_channels(conv->channels() / conv->groups()); config.inputDefs.push_back( {INPUT_DATA, "layer_0", CHANNELS * IMAGE_SIZE * IMAGE_SIZE_Y * IMAGE_SIZE_Z, conv->filter_channels() * FILTER_SIZE * FILTER_SIZE_Y * FILTER_SIZE_Z * NUM_FILTERS}); testLayerGrad(config, "conv3D", 10, trans, useGpu); // Use small batch_size and useWeight=true to test biasGrad testLayerGrad(config, "conv3D", 2, trans, useGpu, true, 0.02); } TEST(Layer, test3DConvLayer) { test3DConvLayer("conv3d", /* trans= */ false, /* useGpu= */ false); #ifdef PADDLE_WITH_CUDA test3DConvLayer("conv3d", /* trans= */ false, /* useGpu= */ true); #endif } void test3DDeConvLayer(const string& type, bool trans, bool useGpu) { // filter size const int NUM_FILTERS = 6; // const int CHANNELS = 3; const int FILTER_SIZE = 3; const int FILTER_SIZE_Y = 3; const int FILTER_SIZE_Z = 3; // input image const int CHANNELS = 3; const int IMAGE_SIZE = 4; const int IMAGE_SIZE_Y = 6; const int IMAGE_SIZE_Z = 6; // Setting up conv-trans layer TestConfig config; config.biasSize = NUM_FILTERS; config.layerConfig.set_type("deconv3d"); config.layerConfig.set_num_filters(NUM_FILTERS); config.layerConfig.set_partial_sum(1); config.layerConfig.set_shared_biases(true); LayerInputConfig* input = config.layerConfig.add_inputs(); ConvConfig* conv = input->mutable_conv_conf(); conv->set_channels(CHANNELS); conv->set_filter_size(FILTER_SIZE); conv->set_filter_size_y(FILTER_SIZE_Y); conv->set_filter_size_z(FILTER_SIZE_Z); conv->set_padding(0); conv->set_padding_y(0); conv->set_padding_z(0); conv->set_stride(2); conv->set_stride_y(2); conv->set_stride_z(2); conv->set_output_x(IMAGE_SIZE); conv->set_output_y(IMAGE_SIZE_Y); conv->set_output_z(IMAGE_SIZE_Z); conv->set_img_size(imageSize(conv->output_x(), conv->filter_size(), conv->padding(), conv->stride(), true)); conv->set_img_size_y(imageSize(conv->output_y(), conv->filter_size_y(), conv->padding_y(), conv->stride_y(), true)); conv->set_img_size_z(imageSize(conv->output_z(), conv->filter_size_z(), conv->padding_z(), conv->stride_z(), true)); config.layerConfig.set_size(conv->img_size() * conv->img_size_y() * conv->img_size_z() * NUM_FILTERS); conv->set_groups(1); conv->set_filter_channels(conv->channels() / conv->groups()); config.inputDefs.push_back( {INPUT_DATA, "layer_0", CHANNELS * IMAGE_SIZE * IMAGE_SIZE_Y * IMAGE_SIZE_Z, conv->filter_channels() * FILTER_SIZE * FILTER_SIZE_Y * FILTER_SIZE_Z * NUM_FILTERS}); testLayerGrad(config, "deconv3D", 10, trans, useGpu); // Use small batch_size and useWeight=true to test biasGrad testLayerGrad(config, "deconv3D", 2, trans, useGpu, true, 0.02); } TEST(Layer, test3DDeConvLayer) { test3DDeConvLayer("deconv3d", /* trans= */ false, /* useGpu= */ false); #ifdef PADDLE_WITH_CUDA test3DDeConvLayer("deconv3d", /* trans= */ false, /* useGpu= */ true); #endif } TEST(Layer, ScaleShiftLayer) { const size_t batchSize = 16; const size_t size = 32; TestConfig config; config.layerConfig.set_type("scale_shift"); config.layerConfig.set_size(size); config.biasSize = 1; config.inputDefs.push_back( {INPUT_DATA, "input", /* dim= */ size, /* paraSize= */ 1}); config.layerConfig.add_inputs(); for (auto useGpu : {false, true}) { testLayerGrad(config, "scale_shift", batchSize, false, useGpu, false); } } void testFactorizationMachineLayer(InputType type, bool useGpu) { const int FACTOR_SIZE = 10; TestConfig config; config.layerConfig.set_type("factorization_machine"); config.layerConfig.set_factor_size(FACTOR_SIZE); config.layerConfig.set_size(1); config.biasSize = 0; config.inputDefs.push_back({type, "layer_0", 128, 1280}); config.layerConfig.add_inputs(); testLayerGrad(config, "factorization_machine", 16, false, useGpu, false); } TEST(Layer, FactorizationMachineLayer) { for (auto useGpu : {false, true}) { testFactorizationMachineLayer(INPUT_DATA, useGpu); } } int main(int argc, char** argv) { testing::InitGoogleTest(&argc, argv); initMain(argc, argv); FLAGS_thread_local_rand_use_global_seed = true; srand(1); return RUN_ALL_TESTS(); }