/* Copyright (c) 2022 PaddlePaddle Authors. All Rights Reserved. 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. */ #include "paddle/phi/infermeta/multiary.h" #include #include "paddle/phi/common/layout.h" #include "paddle/phi/common/scalar.h" #include "paddle/phi/core/infermeta_utils.h" #include "paddle/phi/core/meta_tensor.h" #include "paddle/phi/kernels/funcs/concat_funcs.h" namespace phi { std::vector GetMetaTensorsDim(const std::vector& tensors) { std::vector dims; dims.reserve(tensors.size()); for (const MetaTensor* tensor : tensors) { dims.emplace_back(tensor->dims()); } return dims; } void AdadeltaInferMeta(const MetaTensor& param, const MetaTensor& grad, const MetaTensor& avg_squared_grad, const MetaTensor& avg_squared_update, float rho, float epsilon, MetaTensor* param_out, MetaTensor* avg_squared_grad_out, MetaTensor* avg_squared_update_out) { auto param_dims = param.dims(); PADDLE_ENFORCE_EQ( param_dims, grad.dims(), errors::InvalidArgument( "Param and grad input of AdadeltaOp should have same dimension.")); PADDLE_ENFORCE_EQ( param_dims, avg_squared_grad.dims(), errors::InvalidArgument("Param and AvgSquaredGrad input of AdadeltaOp " "should have same dimension")); PADDLE_ENFORCE_EQ( param_dims, avg_squared_update.dims(), errors::InvalidArgument("Param and AvgSquaredUpdate input of AdadeltaOp " "should have same dimension")); param_out->set_dims(param_dims); param_out->set_dtype(param.dtype()); avg_squared_grad_out->set_dims(param_dims); avg_squared_grad_out->set_dtype(avg_squared_grad.dtype()); avg_squared_update_out->set_dims(param_dims); avg_squared_update_out->set_dtype(avg_squared_update.dtype()); } void AdagradInferMeta(const MetaTensor& param, const MetaTensor& grad, const MetaTensor& moment, const MetaTensor& learning_rate, float epsilon, MetaTensor* param_out, MetaTensor* moment_out) { auto lr_dims = learning_rate.dims(); PADDLE_ENFORCE_EQ( phi::product(lr_dims), 1, phi::errors::InvalidArgument("LearningRate should have one element")); auto param_dims = param.dims(); PADDLE_ENFORCE_EQ( param_dims, moment.dims(), phi::errors::InvalidArgument("Param and Moment input of AdagradOp " "should have the same dimension.")); param_out->set_dims(param_dims); param_out->set_dtype(param.dtype()); moment_out->set_dims(param_dims); moment_out->set_dtype(moment.dtype()); } void AdamaxInferMeta(const MetaTensor& param, const MetaTensor& grad, const MetaTensor& learning_rate, const MetaTensor& moment, const MetaTensor& inf_norm, const MetaTensor& beta1_pow, float beta1, float beta2, float epsilon, MetaTensor* param_out, MetaTensor* moment_out, MetaTensor* inf_norm_out) { auto lr_dims = learning_rate.dims(); PADDLE_ENFORCE_NE( product(lr_dims), 0, errors::InvalidArgument("Maybe the Input variable LearningRate has not " "been initialized. You may need to confirm " "if you put exe.run(startup_program) " "after optimizer.minimize function.")); PADDLE_ENFORCE_EQ( product(lr_dims), 1, errors::InvalidArgument("Learning rate should have 1 dimension")); auto beta1_pow_dims = beta1_pow.dims(); PADDLE_ENFORCE_EQ(product(beta1_pow_dims), 1, errors::InvalidArgument( "Beta1 power accumulator should have 1 dimension")); auto param_dims = param.dims(); PADDLE_ENFORCE_EQ( param_dims, grad.dims(), errors::InvalidArgument( "Param and Grad input of AdamaxOp should have same dimension")); PADDLE_ENFORCE_EQ( param_dims, moment.dims(), errors::InvalidArgument( "Param and Moment input of AdamaxOp should have same dimension")); PADDLE_ENFORCE_EQ( param_dims, inf_norm.dims(), errors::InvalidArgument( "Param and InfNorm input of AdamaxOp should have same dimension")); param_out->set_dims(param_dims); param_out->set_dtype(param.dtype()); moment_out->set_dims(param_dims); moment_out->set_dtype(moment.dtype()); inf_norm_out->set_dims(param_dims); inf_norm_out->set_dtype(inf_norm.dtype()); } void AddNInferMeta(const std::vector& x, MetaTensor* out, MetaConfig config) { auto N = x.size(); PADDLE_ENFORCE_GT( N, 0, phi::errors::InvalidArgument( "The input tensor X's dimensions of SumOp " "should be larger than 0. But received X's dimensions %d.", N)); if (N == 1) { VLOG(3) << "Warning: SumOp have only one input, may waste memory"; } phi::DDim in_dim({0}); for (size_t i = 0; i < x.size(); ++i) { auto x_dim = x[i]->dims(); if (phi::product(x_dim) == 0) { continue; } if (phi::product(in_dim) == 0) { in_dim = x_dim; } else { if (config.is_runtime) { PADDLE_ENFORCE_EQ(in_dim, x_dim, phi::errors::InvalidArgument( "The input tensor X of SumOp must" " have same shape. But received X[0]'s shape = " "[%s], X[%d]'s shape = [%s].", in_dim, i, x_dim)); } else { PADDLE_ENFORCE_EQ( in_dim.size(), x_dim.size(), phi::errors::InvalidArgument( "The input tensor X of SumOp must have same " "dimensions. But received X[0]'s dimensions = %d, X[0]'s " "shape = " "[%s], X[%d]'s dimensions = %d, X[%d]'s shape = [%s].", in_dim.size(), in_dim, i, x_dim.size(), i, x_dim)); // if in_dim or x_dim has -1, not check equal for (int j = 0; j < x_dim.size(); ++j) { if (x_dim[j] == -1 || in_dim[j] == -1) { continue; } PADDLE_ENFORCE_EQ( in_dim[j], x_dim[j], phi::errors::InvalidArgument( "The input tensor X of SumOp must have same shape " "if not -1." "But received X[0]'s shape = [%s], X[%d]'s shape = [%s].", in_dim, i, x_dim)); } } } } out->set_dims(in_dim); out->share_lod(*x[0]); } void AucInferMeta(const MetaTensor& input, const MetaTensor& label, const MetaTensor& stat_pos, const MetaTensor& stat_neg, const std::string& curve, int num_thresholds, int slide_steps, MetaTensor* auc, MetaTensor* stat_pos_out, MetaTensor* stat_neg_out, MetaConfig config) { auto predict_dims = input.dims(); auto label_dims = label.dims(); PADDLE_ENFORCE_GE( predict_dims.size(), 2, phi::errors::InvalidArgument( "The Input(Predict) has not been initialized properly. The " "shape of Input(Predict) = [%s], the shape size must be " "greater_equal 2.", predict_dims)); auto predict_width = predict_dims[1]; PADDLE_ENFORCE_NE( phi::product(predict_dims), 0, phi::errors::InvalidArgument( "The Input(Predict) has not been initialized properly. The " "shape of Input(Predict) = [%s], the shape can not involes 0.", predict_dims)); PADDLE_ENFORCE_NE( phi::product(label_dims), 0, phi::errors::InvalidArgument( "The Input(Label) has not been initialized properly. The " "shape of Input(Label) = [%s], the shape can not involes 0.", label_dims)); if (config.is_runtime) { PADDLE_ENFORCE_LE( predict_width, 2, phi::errors::InvalidArgument("Only support binary classification," "prediction dims[1] should be 1 or 2")); } auto predict_height = input.dims()[0]; auto label_height = label.dims()[0]; if (config.is_runtime) { PADDLE_ENFORCE_EQ( predict_height, label_height, phi::errors::InvalidArgument("Out and Label should have same height.")); } int num_pred_buckets = num_thresholds + 1; PADDLE_ENFORCE_GE( num_pred_buckets, 1, phi::errors::InvalidArgument("num_thresholds must larger than 1")); PADDLE_ENFORCE_GE( slide_steps, 0, phi::errors::InvalidArgument("slide_steps must be natural number")); auc->set_dims({1}); auc->set_dtype(DataType::INT64); if (slide_steps) { stat_pos_out->set_dims({(1 + slide_steps) * num_pred_buckets + 1}); stat_pos_out->set_dtype(DataType::INT64); stat_neg_out->set_dims({(1 + slide_steps) * num_pred_buckets + 1}); stat_neg_out->set_dtype(DataType::INT64); } else { stat_pos_out->set_dims({1, num_pred_buckets}); stat_pos_out->set_dtype(DataType::INT64); stat_neg_out->set_dims({1, num_pred_buckets}); stat_neg_out->set_dtype(DataType::INT64); } } void BatchNormInferMeta(const MetaTensor& x, const MetaTensor& scale, const MetaTensor& bias, const MetaTensor& mean, const MetaTensor& variance, float momentum, float epsilon, const std::string& data_layout_str, bool is_test, bool use_global_stats, bool trainable_statistics, bool fuse_with_relu, MetaTensor* y, MetaTensor* mean_out, MetaTensor* variance_out, MetaTensor* saved_mean, MetaTensor* saved_variance, MetaTensor* reserve_space, MetaConfig config) { const auto x_dims = x.dims(); for (int i = 0; i < x_dims.size(); i++) { PADDLE_ENFORCE_EQ( (x_dims[i] == -1) || (x_dims[i] > 0), true, phi::errors::InvalidArgument( "Each dimension of input tensor is expected to be -1 or a " "positive number, but recieved %d. Input's shape is [%s].", x_dims[i], x_dims)); } const DataLayout data_layout = paddle::framework::StringToDataLayout(data_layout_str); PADDLE_ENFORCE_GE( x_dims.size(), 2, phi::errors::InvalidArgument( "ShapeError: the dimension of input " "X must greater than or equal to 2. But received: the shape of input " "X = [%s], the dimension of input X =[%d]", x_dims, x_dims.size())); PADDLE_ENFORCE_LE( x_dims.size(), 5, phi::errors::InvalidArgument( "ShapeError: the dimension of input X " "must smaller than or equal to 5. But received: the shape of input X " "= [%s], the dimension of input X = [%d]", x_dims, x_dims.size())); const int64_t C = ((config.is_run_mkldnn_kernel == true) || (data_layout == DataLayout::kNCHW) ? x_dims[1] : x_dims[x_dims.size() - 1]); auto scale_dim = scale.dims(); auto bias_dim = bias.dims(); PADDLE_ENFORCE_EQ( scale_dim.size(), 1UL, phi::errors::InvalidArgument( "ShapeError: the dimension of scale must equal to 1." "But received: the shape of scale is [%s], the dimension " "of scale is [%d]", scale_dim, scale_dim.size())); PADDLE_ENFORCE_EQ(bias_dim.size(), 1UL, phi::errors::InvalidArgument( "ShapeError: the dimension of bias must equal to 1." "But received: the shape of bias is [%s],the dimension " "of bias is [%d]", bias_dim, bias_dim.size())); bool check = true; if ((!config.is_runtime) && (phi::product(scale_dim) <= 0 || phi::product(bias_dim) <= 0)) { check = false; } if (check) { PADDLE_ENFORCE_EQ(scale_dim[0], C, phi::errors::InvalidArgument( "ShapeError: the shape of scale must equal to [%d]" "But received: the shape of scale is [%d]", C, scale_dim[0])); PADDLE_ENFORCE_EQ(bias_dim[0], C, phi::errors::InvalidArgument( "ShapeError: the shape of bias must equal to [%d]" "But received: the shape of bias is [%d]", C, bias_dim[0])); } y->set_dims(x_dims); mean_out->set_dims({C}); variance_out->set_dims({C}); if (saved_mean) { saved_mean->set_dims({C}); } if (saved_variance) { saved_variance->set_dims({C}); } y->share_lod(x); } void BatchNormInferInferMeta(const MetaTensor& x, const MetaTensor& scale, const MetaTensor& bias, const MetaTensor& mean, const MetaTensor& variance, float momentum, float epsilon, const std::string& data_layout, MetaTensor* y, MetaTensor* mean_out, MetaTensor* variance_out, MetaConfig config) { BatchNormInferMeta(x, scale, bias, mean, variance, momentum, epsilon, data_layout, /*is_test=*/true, /*use_global_stats=*/false, /*trainable_statistics=*/false, /*fuse_with_relu=*/false, y, mean_out, variance_out, /*saved_mean=*/nullptr, /*saved_variance=*/nullptr, /*reserve_space=*/nullptr, config); } void BilinearTensorProductInferMeta(const MetaTensor& x, const MetaTensor& y, const MetaTensor& weight, paddle::optional bias, MetaTensor* out, MetaConfig config) { auto x_dims = x.dims(); auto y_dims = y.dims(); auto weight_dims = weight.dims(); PADDLE_ENFORCE_EQ( x_dims.size(), 2UL, errors::InvalidArgument("The input(X) must be a 2D Tensor.")); PADDLE_ENFORCE_EQ( y_dims.size(), 2UL, errors::InvalidArgument("The input(Y) must be a 2D Tensor.")); PADDLE_ENFORCE_EQ( weight_dims.size(), 3UL, errors::InvalidArgument( "Expected the input(Weight) is a 3D tensor. But received %dD tensor.", weight_dims.size())); if (config.is_runtime || (x_dims[0] > 0 && y_dims[0] > 0)) { PADDLE_ENFORCE_EQ(x_dims[0], y_dims[0], errors::InvalidArgument( "The first dimension(batch_size) of input(X) must be " "equal to the first dimension of the input(Y).")); } PADDLE_ENFORCE_EQ(x_dims[1], weight_dims[1], errors::InvalidArgument( "The second dimension of input(X) must be equal to " "the second dimension of the input(Weight).")); PADDLE_ENFORCE_EQ(y_dims[1], weight_dims[2], errors::InvalidArgument( "The second dimension of input(Y) must be equal to " "the third dimension of the input(Weight).")); if (bias.get_ptr()) { auto bias_dims = bias->dims(); PADDLE_ENFORCE_EQ(bias_dims.size(), 2UL, errors::InvalidArgument( "The Input(Bias) must be a 2-D tensor with " "the 2nd dimension fixed to 1 (a row vector).")); PADDLE_ENFORCE_EQ(bias_dims[0], 1UL, errors::InvalidArgument( "The Input(Bias) must be a 2-D tensor with " "the 2nd dimension fixed to 1 (a row vector).")); PADDLE_ENFORCE_EQ(bias_dims[1], weight_dims[0], errors::InvalidArgument( "The second dimension of input(Bias) must be equal " "to the first dimension of the input(Weight).")); } out->set_dims({x_dims[0], weight_dims[0]}); out->share_lod(x); out->set_dtype(x.dtype()); } void BroadcastTensorsInferMeta(const std::vector& x, std::vector out) { int target_rank = 0; const auto& input_dims = GetMetaTensorsDim(x); // 1. Find Output rank = max(Inputs rank) for (const auto& input_ddim : input_dims) { target_rank = std::max(target_rank, input_ddim.size()); } PADDLE_ENFORCE_GT(target_rank, 0, errors::InvalidArgument("BroadcastTensorsOp requires at " "least one input tensor to have " "rank greater than zero")); std::vector target_dims(target_rank, 0); // 2. Output dim(axis=x) = max(Inputs dim(axis=x)) for (int index = 0; index < target_rank; index++) { // Loop axes in reverse order, // For each axis, take the maximum as target size // Fill size = 1 if shape vector exhausts int target_dim_size = 1; for (const auto& input_ddim : input_dims) { // Reversed order int axis = static_cast(input_ddim.size()) - index - 1; int dim_size = 1; if (axis >= 0) { dim_size = input_ddim[axis]; } if (target_dim_size != 1 && dim_size != 1 && target_dim_size != dim_size) { PADDLE_THROW(errors::InvalidArgument( "BroadcastTensorsOp inputs does not satisfy bcast semantics, " "please check axis = %d in reverse order", index)); } // We performed bcast semantics check at python level // So input tensors should all have legal shape target_dim_size = std::max(target_dim_size, dim_size); } target_dims[target_rank - index - 1] = target_dim_size; } // 3. Set Output Dim for (size_t i = 0; i < out.size(); i++) { out[i]->set_dims(phi::make_ddim(target_dims)); out[i]->share_lod(*(x[i])); out[i]->set_dtype(x[i]->dtype()); } } void ConcatInferMeta(const std::vector& x, const Scalar& axis_scalar, MetaTensor* out, MetaConfig config) { PADDLE_ENFORCE_GE(x.size(), 0UL, phi::errors::InvalidArgument( "The size of input meta vector should be greater" "than 0.")); if (axis_scalar.FromTensor()) { auto out_dims = phi::make_ddim(std::vector(x.at(0)->dims().size(), -1)); out->set_dims(out_dims); out->set_dtype(x.at(0)->dtype()); out->set_layout(x.at(0)->layout()); out->share_lod(*x.at(0)); return; } int axis = axis_scalar.to(); // 1. calculate axis int rank = x.at(0)->dims().size(); PADDLE_ENFORCE_EQ( axis >= -rank && axis < rank, true, phi::errors::InvalidArgument( "The axis is expected to be in range of [%d, %d), but got %d", -rank, rank, axis)); if (axis < 0) { axis = axis + rank; } // 2. calculate out dims std::vector x_dims; x_dims.reserve(x.size()); for (const auto* x_t : x) { x_dims.emplace_back(x_t->dims()); } phi::DDim out_dim = phi::funcs::ComputeAndCheckShape(config.is_runtime, x_dims, axis); out->set_dims(out_dim); out->set_dtype(x.at(0)->dtype()); out->set_layout(x.at(0)->layout()); out->share_lod(*x.at(0)); } inline int ConvOutputSize( int input_size, int filter_size, int dilation, int padding, int stride) { const int dkernel = dilation * (filter_size - 1) + 1; int output_size = (input_size + 2 * padding - dkernel) / stride + 1; PADDLE_ENFORCE_GT( output_size, 0, phi::errors::InvalidArgument( "The output's size is expected to be greater than 0. " "But recieved: output's size is %d. The output's size is computed by " "((input_size + 2 * padding - (dilation * (filter_size - 1) + 1)) / " "stride + 1), where input_size is %d, padding is %d, " "filter_size is %d, dilation is %d, stride is %d.", output_size, input_size, padding, filter_size, dilation, stride)); return output_size; } void DeformableConvInferMeta(const MetaTensor& x, const MetaTensor& offset, const MetaTensor& filter, paddle::optional mask, const std::vector& strides, const std::vector& paddings, const std::vector& dilations, int deformable_groups, int groups, int im2col_step, MetaTensor* out, MetaConfig config) { auto in_dims = x.dims(); auto offset_dims = offset.dims(); auto filter_dims = filter.dims(); PADDLE_ENFORCE_EQ( in_dims.size(), 4, phi::errors::InvalidArgument("Conv input should be 4-D tensor, get %u", in_dims.size())); PADDLE_ENFORCE_EQ(in_dims.size(), filter_dims.size(), phi::errors::InvalidArgument( "Conv input dimension and filter dimension should be " "the same. The difference is [%d]: [%d]", in_dims.size(), filter_dims.size())); PADDLE_ENFORCE_EQ(in_dims.size() - strides.size(), 2U, phi::errors::InvalidArgument( "Conv input dimension and strides " "dimension should be consistent. But received input " "dimension:[%d], strides dimension:[%d]", in_dims.size(), strides.size())); PADDLE_ENFORCE_EQ(paddings.size(), strides.size(), phi::errors::InvalidArgument( "Conv paddings dimension and Conv strides dimension " "should be the same. The difference is [%d]: [%d]", paddings.size(), strides.size())); PADDLE_ENFORCE_EQ( in_dims[1], filter_dims[1] * groups, phi::errors::InvalidArgument( "The number of input channels should be equal to filter " "channels * groups. The difference is [%d]: [%d]", in_dims[1], filter_dims[1] * groups)); PADDLE_ENFORCE_EQ( filter_dims[0] % groups, 0, phi::errors::InvalidArgument( "The number of output channels should be divided by groups. But " "received output channels:[%d], groups:[%d]", filter_dims[0], groups)); PADDLE_ENFORCE_EQ( filter_dims[0] % deformable_groups, 0, phi::errors::InvalidArgument( "The number of output channels should be " "divided by deformable groups. The difference is [%d]: [%d]", filter_dims[0] % groups, 0)); if (in_dims[0] > im2col_step) { PADDLE_ENFORCE_EQ( in_dims[0] % im2col_step, 0U, phi::errors::InvalidArgument( "Input batchsize must be smaller than or divide im2col_step. But " "received Input batchsize:[%d], im2col_step:[%d]", in_dims[0], im2col_step)); } for (size_t i = 0; i < strides.size(); ++i) { PADDLE_ENFORCE_GT( strides[i], 0U, phi::errors::InvalidArgument("stride %d size incorrect", i)); } for (size_t i = 0; i < dilations.size(); ++i) { PADDLE_ENFORCE_GT( dilations[i], 0U, phi::errors::InvalidArgument("dilation %d size incorrect", i)); } std::vector output_shape({in_dims[0], filter_dims[0]}); for (size_t i = 0; i < strides.size(); ++i) { if (!config.is_runtime && (in_dims[i + 2] <= 0 || filter_dims[i + 2] <= 0)) { output_shape.push_back(-1); } else { output_shape.push_back(ConvOutputSize(in_dims[i + 2], filter_dims[i + 2], dilations[i], paddings[i], strides[i])); } } PADDLE_ENFORCE_EQ( output_shape[1] % deformable_groups, 0U, phi::errors::InvalidArgument( "output num_filter must divide deformable group size. But received " "output num_filter:[%d], deformable group size:[%d]", output_shape[1], deformable_groups)); if (config.is_runtime) { PADDLE_ENFORCE_EQ(output_shape[2], offset_dims[2], phi::errors::InvalidArgument( "output height must equal to offset map height. " "The difference is [%d]: [%d]", output_shape[2], offset_dims[2])); PADDLE_ENFORCE_EQ(output_shape[3], offset_dims[3], phi::errors::InvalidArgument( "output width must equal to offset map width. The " "difference is [%d]: [%d]", output_shape[3], offset_dims[3])); PADDLE_ENFORCE_EQ(offset_dims[1] % (filter_dims[2] * filter_dims[3]), 0U, phi::errors::InvalidArgument( "offset filter must divide deformable group size. " "But received [%d]: [%d]", offset_dims[1], filter_dims[2] * filter_dims[3])); PADDLE_ENFORCE_EQ( offset_dims[1] / (2 * filter_dims[2] * filter_dims[3]), deformable_groups, phi::errors::InvalidArgument( "offset filter must divide deformable group size. But received " "[%d]: [%d]", offset_dims[1] / (2 * filter_dims[2] * filter_dims[3]), deformable_groups)); if (mask) { auto mask_dims = mask->dims(); PADDLE_ENFORCE_EQ(output_shape[2], mask_dims[2], phi::errors::InvalidArgument( "output height must equal to mask map height. The " "difference is [%d] vs [%d]", output_shape[2], mask_dims[2])); PADDLE_ENFORCE_EQ(output_shape[3], mask_dims[3], phi::errors::InvalidArgument( "output width must equal to mask map width. The " "difference is [%d] vs [%d]", output_shape[3], mask_dims[3])); PADDLE_ENFORCE_EQ(mask_dims[1] % (filter_dims[2] * filter_dims[3]), 0U, phi::errors::InvalidArgument( "mask filter must divide deformable group size. " "But received [%d]: [%d]", mask_dims[1], filter_dims[2] * filter_dims[3])); PADDLE_ENFORCE_EQ(mask_dims[1] / (filter_dims[2] * filter_dims[3]), deformable_groups, phi::errors::InvalidArgument( "mask filter must divide deformable group size. " "But received [%d]: [%d]", mask_dims[1] / (filter_dims[2] * filter_dims[3]), deformable_groups)); } } out->set_dims(phi::make_ddim(output_shape)); out->set_dtype(x.dtype()); } void HierarchicalSigmoidInferMeta(const MetaTensor& x, const MetaTensor& w, const MetaTensor& label, paddle::optional path, paddle::optional code, paddle::optional bias, int num_classes, bool remote_prefetch, int trainer_id, const std::vector& height_sections, const std::vector& epmap, const std::vector& table_names, bool is_sparse, MetaTensor* out, MetaTensor* pre_out, MetaTensor* w_out) { const int64_t input_dims = x.dims()[0]; const int64_t label_dims = label.dims()[0]; PADDLE_ENFORCE_EQ(input_dims, label_dims, phi::errors::InvalidArgument( "The first dimension of " "input and label is expected to be the same. " "But received input's first dimension is %d; " "label's first dimension is %d.", input_dims, label_dims)); std::vector output_shape({input_dims, 1}); out->set_dims(phi::make_ddim(output_shape)); out->share_lod(x); out->set_dtype(x.dtype()); } static void Interpolate1DInferShapeCheck( const MetaTensor& x, paddle::optional out_size, paddle::optional> size_tensor, paddle::optional scale_tensor, const std::string& data_layout_str, int out_d, int out_h, int out_w, const std::vector& scale, const std::string& interp_method, bool align_corners, int align_mode, MetaTensor* output, MetaConfig config) { auto dim_x = x.dims(); PADDLE_ENFORCE_EQ("linear", interp_method, phi::errors::InvalidArgument( "Interpolation method can only be \"linear\" when" "Input(X) dimension is 3, but got method = %s .", interp_method)); const DataLayout data_layout = paddle::framework::StringToDataLayout(data_layout_str); for (int i = 0; i < dim_x.size(); ++i) { PADDLE_ENFORCE_NE( dim_x[i], 0, phi::errors::InvalidArgument("The shape of input(x) should be larged " "than 0, bug received shape[%d] is %d ", i, dim_x[i])); } if (size_tensor && size_tensor->size() > 0) { // top prority size auto inputs_name = size_tensor.get(); PADDLE_ENFORCE_EQ( inputs_name.size(), 1, phi::errors::InvalidArgument( "Input(SizeTensor)'size of Op(interpolate) must be 1. " "Attr(out_shape)'s length must be 1 for 3-D input tensor, but got " "size = %d .", inputs_name.size())); phi::DDim dim_out; if (data_layout == DataLayout::kNCHW) { dim_out = {dim_x[0], dim_x[1], out_w}; } else { dim_out = {dim_x[0], out_w, dim_x[2]}; } output->set_dims(dim_out); output->set_dtype(x.dtype()); return; } int out_w_tmp; if (scale_tensor) { auto scale_tensor_dim = scale_tensor->dims(); PADDLE_ENFORCE_EQ( scale_tensor_dim.size(), 1, phi::errors::InvalidArgument( "Scale's dimension size must be 1, but got dimension = %d .", scale_tensor_dim.size())); PADDLE_ENFORCE_EQ(scale_tensor_dim[0], 1, phi::errors::InvalidArgument( "Scale's shape must be 1, but got shape = %d .", scale_tensor_dim[0])); out_w_tmp = -1; } else { if (scale.size() > 0) { float scale_w = -1; scale_w = scale[0]; PADDLE_ENFORCE_EQ( scale_w > 0, true, phi::errors::InvalidArgument( "The scale_w in Attr(scale) of Operator(interpolate) " "should be greater than 0, but received value is %d.", scale_w)); if (scale_w > 0.) { // round down out_w_tmp = (data_layout == DataLayout::kNCHW ? static_cast(dim_x[2] * scale_w) : static_cast(dim_x[1] * scale_w)); // protect when input shape is -1 out_w_tmp = out_w_tmp > 0 ? out_w_tmp : -1; } } else { out_w_tmp = out_w; } } if (out_size && config.is_runtime) { auto out_size_dim = out_size->dims(); PADDLE_ENFORCE_EQ( out_size_dim.size(), 1, phi::errors::InvalidArgument( "OutSize's dimension size must be 1, but got dimention = %d .", out_size_dim.size())); PADDLE_ENFORCE_EQ( out_size_dim[0], 1, phi::errors::InvalidArgument( "OutSize's 0-th dimension's value must be 1, but got value = %d .", out_size_dim[0])); // dims will be seted in kernel output->set_dtype(x.dtype()); output->share_lod(x); return; } phi::DDim dim_out; if (data_layout == DataLayout::kNCHW) { dim_out = {dim_x[0], dim_x[1], out_w_tmp}; } else { dim_out = {dim_x[0], out_w_tmp, dim_x[2]}; } output->set_dims(dim_out); output->set_dtype(x.dtype()); } static void Interpolate2DInferShapeCheck( const MetaTensor& x, paddle::optional out_size, paddle::optional> size_tensor, paddle::optional scale_tensor, const std::string& data_layout_str, int out_d, int out_h, int out_w, const std::vector& scale, const std::string& interp_method, bool align_corners, int align_mode, MetaTensor* output, MetaConfig config) { auto dim_x = x.dims(); PADDLE_ENFORCE( "bilinear" == interp_method || "nearest" == interp_method || "bicubic" == interp_method, phi::errors::InvalidArgument( "Interpolation method can only be \"bilinear\" or \"nearest\" when " "Input(X) dimension is 4, but got method = %s.", interp_method)); const DataLayout data_layout = paddle::framework::StringToDataLayout(data_layout_str); for (int i = 0; i < dim_x.size(); ++i) { PADDLE_ENFORCE_NE( dim_x[i], 0, phi::errors::InvalidArgument("The shape of input(x) should be larged " "than 0, bug received shape[%d] is %d ", i, dim_x[i])); } if (size_tensor && size_tensor->size()) { // top prority size auto inputs_name = size_tensor.get(); PADDLE_ENFORCE_EQ( inputs_name.size(), 2, phi::errors::InvalidArgument( "Input(SizeTensor)'size of Op(interpolate) must be 2. " "Attr(out_shape)'s length must be 2 for 4-D input " "tensor, but got size = %d .", inputs_name.size())); phi::DDim dim_out; if (data_layout == DataLayout::kNCHW) { dim_out = {dim_x[0], dim_x[1], out_h, out_w}; } else { dim_out = {dim_x[0], out_h, out_w, dim_x[3]}; } output->set_dims(dim_out); output->set_dtype(x.dtype()); return; } int out_h_tmp, out_w_tmp; if (scale_tensor) { auto scale_tensor_dim = scale_tensor->dims(); PADDLE_ENFORCE_EQ( scale_tensor_dim.size(), 1, phi::errors::InvalidArgument( "Scale's dimension size must be 1, but got dimension = %d .", scale_tensor_dim.size())); PADDLE_ENFORCE_EQ(scale_tensor_dim[0] == 2 || scale_tensor_dim[0] == 1, true, phi::errors::InvalidArgument( "Scale's shape must be 2 or 1, but got shape = %d .", scale_tensor_dim[0])); out_h_tmp = -1; out_w_tmp = -1; } else { if (scale.size() > 0) { float scale_h = -1; float scale_w = -1; scale_h = scale[0]; scale_w = scale[1]; PADDLE_ENFORCE_EQ( scale_w > 0, true, phi::errors::InvalidArgument( "The scale_w in Attr(scale) of Operator(interpolate) " "should be greater than 0, but received value is %d.", scale_w)); PADDLE_ENFORCE_EQ( scale_h > 0, true, phi::errors::InvalidArgument( "The scale_h in Attr(scale) of Operator(interpolate) " "should be greater than 0, but received value is %d.", scale_h)); if (scale_h > 0. && scale_w > 0.) { // round down out_h_tmp = (data_layout == DataLayout::kNCHW ? static_cast(dim_x[2] * scale_h) : static_cast(dim_x[1] * scale_h)); out_w_tmp = (data_layout == DataLayout::kNCHW ? static_cast(dim_x[3] * scale_w) : static_cast(dim_x[2] * scale_w)); // protect when input shape is -1 out_h_tmp = out_h_tmp > 0 ? out_h_tmp : -1; out_w_tmp = out_w_tmp > 0 ? out_w_tmp : -1; } } else { out_h_tmp = out_h; out_w_tmp = out_w; } } if (out_size && config.is_runtime) { auto out_size_dim = out_size->dims(); PADDLE_ENFORCE_EQ( out_size_dim.size(), 1, phi::errors::InvalidArgument( "OutSize's dimension size must be 1, but got dimension = %d .", out_size_dim.size())); PADDLE_ENFORCE_EQ( out_size_dim[0], 2, phi::errors::InvalidArgument( "OutSize's dim[0] must be 2, but got dimention = %d .", out_size_dim[0])); // dims will be seted in kernel output->set_dtype(x.dtype()); output->share_lod(x); return; } phi::DDim dim_out; if (data_layout == DataLayout::kNCHW) { dim_out = {dim_x[0], dim_x[1], out_h_tmp, out_w_tmp}; } else { dim_out = {dim_x[0], out_h_tmp, out_w_tmp, dim_x[3]}; } output->set_dims(dim_out); output->set_dtype(x.dtype()); } static void Interpolate3DInferShapeCheck( const MetaTensor& x, paddle::optional out_size, paddle::optional> size_tensor, paddle::optional scale_tensor, const std::string& data_layout_str, int out_d, int out_h, int out_w, const std::vector& scale, const std::string& interp_method, bool align_corners, int align_mode, MetaTensor* output, MetaConfig config) { auto dim_x = x.dims(); PADDLE_ENFORCE("nearest" == interp_method || "trilinear" == interp_method, phi::errors::InvalidArgument( "Interpolation method can only be \"trilinear\" or " "\"nearest\" when Input(X) " "dimension is 5, but got method = %s .", interp_method)); const DataLayout data_layout = paddle::framework::StringToDataLayout(data_layout_str); for (int i = 0; i < dim_x.size(); ++i) { PADDLE_ENFORCE_NE( dim_x[i], 0, phi::errors::InvalidArgument("The shape of input(x) should be larged " "than 0, bug received shape[%d] is %d ", i, dim_x[i])); } if (size_tensor && size_tensor->size() > 0) { // top prority size auto inputs_name = size_tensor.get(); PADDLE_ENFORCE_EQ( inputs_name.size(), 3, phi::errors::InvalidArgument( "Input(SizeTensor)'s size of Op(interpolate) must be 3. " "Attr(out_shape)'s length must be 3 for 5-D input " "tensor, but got size = %d .", inputs_name.size())); phi::DDim dim_out; if (data_layout == DataLayout::kNCHW) { dim_out = {dim_x[0], dim_x[1], out_d, out_h, out_w}; } else { dim_out = {dim_x[0], out_d, out_h, out_w, dim_x[4]}; } output->set_dims(dim_out); output->set_dtype(x.dtype()); return; } int out_d_tmp, out_h_tmp, out_w_tmp; if (scale_tensor) { auto scale_tensor_dim = scale_tensor->dims(); PADDLE_ENFORCE_EQ( scale_tensor_dim.size(), 1, phi::errors::InvalidArgument( "Scale's dimension size must be 1, but got size = %d .", scale_tensor_dim.size())); PADDLE_ENFORCE_EQ(scale_tensor_dim[0] == 3 || scale_tensor_dim[0] == 1, true, phi::errors::InvalidArgument( "Scale's shape must be 3 or 1, but got shape = %d .", scale_tensor_dim[0])); out_d_tmp = -1; out_h_tmp = -1; out_w_tmp = -1; } else { if (scale.size() > 0) { float scale_d = -1; float scale_h = -1; float scale_w = -1; scale_d = scale[0]; scale_h = scale[1]; scale_w = scale[2]; PADDLE_ENFORCE_EQ( scale_w > 0, true, phi::errors::InvalidArgument( "The scale_w in Attr(scale) of Operator(interpolate) " "should be greater than 0, but received value is %d.", scale_w)); PADDLE_ENFORCE_EQ( scale_h > 0, true, phi::errors::InvalidArgument( "The scale_h in Attr(scale) of Operator(interpolate) " "should be greater than 0, but received value is %d.", scale_h)); PADDLE_ENFORCE_EQ( scale_d > 0, true, phi::errors::InvalidArgument( "The scale_d in Attr(scale) of Operator(interpolate) " "should be greater than 0, but received value is %d.", scale_d)); if (scale_d > 0. && scale_h > 0. && scale_w > 0.) { // round down out_d_tmp = (data_layout == DataLayout::kNCHW ? static_cast(dim_x[2] * scale_d) : static_cast(dim_x[1] * scale_d)); out_h_tmp = (data_layout == DataLayout::kNCHW ? static_cast(dim_x[3] * scale_h) : static_cast(dim_x[2] * scale_h)); out_w_tmp = (data_layout == DataLayout::kNCHW ? static_cast(dim_x[4] * scale_w) : static_cast(dim_x[3] * scale_w)); // protect when input shape is -1 out_d_tmp = out_d_tmp > 0 ? out_d_tmp : -1; out_h_tmp = out_h_tmp > 0 ? out_h_tmp : -1; out_w_tmp = out_w_tmp > 0 ? out_w_tmp : -1; } } else { out_d_tmp = out_d; out_h_tmp = out_h; out_w_tmp = out_w; } } if (out_size && config.is_runtime) { auto out_size_dim = out_size->dims(); PADDLE_ENFORCE_EQ( out_size_dim.size(), 1, phi::errors::InvalidArgument( "OutSize's dimension size must be 1, but got size is %d.", out_size_dim.size())); PADDLE_ENFORCE_EQ(out_size_dim[0], 3, phi::errors::InvalidArgument( "OutSize's dim[0] must be 3, but got size is %d.", out_size_dim[0])); // dims will be seted in kernel output->set_dtype(x.dtype()); output->share_lod(x); return; } phi::DDim dim_out; if (data_layout == DataLayout::kNCHW) { dim_out = {dim_x[0], dim_x[1], out_d_tmp, out_h_tmp, out_w_tmp}; } else { dim_out = {dim_x[0], out_d_tmp, out_h_tmp, out_w_tmp, dim_x[4]}; } output->set_dims(dim_out); output->set_dtype(x.dtype()); } void InterpolateInferMeta( const MetaTensor& x, paddle::optional out_size, paddle::optional> size_tensor, paddle::optional scale_tensor, const std::string& data_layout_str, int out_d, int out_h, int out_w, const std::vector& scale, const std::string& interp_method, bool align_corners, int align_mode, MetaTensor* output, MetaConfig config) { auto dim_x = x.dims(); // NCHW format PADDLE_ENFORCE( dim_x.size() == 3 || dim_x.size() == 4 || dim_x.size() == 5, phi::errors::Unimplemented( "Input(X) dimension must be 3, 4 or 5, but got dimension = %d .", dim_x.size())); if (dim_x.size() == 3) { // shape check for 1D interpolate for input tensor shape NCHW Interpolate1DInferShapeCheck(x, out_size, size_tensor, scale_tensor, data_layout_str, out_d, out_h, out_w, scale, interp_method, align_corners, align_mode, output, config); } else if (dim_x.size() == 4) { // shape check for 2D interpolate for input tensor shape NCHW Interpolate2DInferShapeCheck(x, out_size, size_tensor, scale_tensor, data_layout_str, out_d, out_h, out_w, scale, interp_method, align_corners, align_mode, output, config); } else { // dim_x.size() == 5 // shape check for 3D interpolate for input tensor shape NCDHW Interpolate3DInferShapeCheck(x, out_size, size_tensor, scale_tensor, data_layout_str, out_d, out_h, out_w, scale, interp_method, align_corners, align_mode, output, config); } } void MeshgridInferMeta(const std::vector& inputs, std::vector outputs) { const size_t inputs_num = inputs.size(); auto out_shape = std::vector(inputs_num); for (size_t i = 0; i < inputs.size(); i++) { out_shape[i] = inputs[i]->dims()[0]; } auto out_dims = phi::make_ddim(std::vector(out_shape)); for (size_t i = 0; i < outputs.size(); ++i) { outputs[i]->set_dims(out_dims); outputs[i]->set_dtype(inputs[0]->dtype()); } } void MomentumInferMeta(const MetaTensor& param, const MetaTensor& grad, const MetaTensor& velocity, const MetaTensor& learning_rate, paddle::optional master_param, float mu, bool use_nesterov, const std::string& regularization_method, float regularization_coeff, bool multi_precision, float rescale_grad, MetaTensor* param_out, MetaTensor* velocity_out, MetaTensor* master_param_out) { PADDLE_ENFORCE_NE( param_out, nullptr, errors::NotFound("Output(ParamOut) of Momentum should not be null.")); PADDLE_ENFORCE_NE( velocity_out, nullptr, errors::NotFound("Output(VelocityOut) of Momentum should not be null.")); auto lr_dims = learning_rate.dims(); PADDLE_ENFORCE_NE( phi::product(lr_dims), 0, errors::InvalidArgument("Maybe the Input variable LearningRate has not " "been initialized. You may need to confirm " "if you put exe.run(startup_program) " "after optimizer.minimize function.")); PADDLE_ENFORCE_EQ( phi::product(lr_dims), 1, errors::InvalidArgument("Learning_rate should be a scalar. But Received " "LearningRate's dim [%s]", phi::product(lr_dims))); auto param_dim = param.dims(); param_out->set_dims(param_dim); velocity_out->set_dims(param_dim); if (master_param_out) { master_param_out->set_dims(param_dim); } } void MultiDotInferMeta(const std::vector& x, MetaTensor* out) { auto inputs_dims = GetMetaTensorsDim(x); const size_t inputs_num = inputs_dims.size(); PADDLE_ENFORCE_GT( inputs_num, static_cast(1), phi::errors::InvalidArgument( "The number of input tensors in multi_dot op should > 1.")); const size_t n = inputs_dims.size(); auto first_dim = inputs_dims[0]; bool is_vector = false; phi::DDim out_dim; PADDLE_ENFORCE_LT( first_dim.size(), static_cast(3), phi::errors::InvalidArgument( "multi_dot: the first input tensor must be 1D or 2D but got[%d]!", static_cast(first_dim.size()))); // If the first tensor is 1D of size n view it as a row vector (1, n) if (first_dim.size() == 1) { first_dim = phi::make_ddim({1, static_cast(first_dim[0])}); is_vector = true; } auto last_dim = inputs_dims[n - 1]; PADDLE_ENFORCE_LT( last_dim.size(), static_cast(3), phi::errors::InvalidArgument( "the last input tensor of multi_dot must be 1D or 2D but got[%d]!", static_cast(first_dim.size()))); // If the last tensor is 1D of size n view it as a column vector (n, 1) if (last_dim.size() == 1) { last_dim = phi::make_ddim({static_cast(last_dim[0]), 1}); out_dim = is_vector ? phi::make_ddim({1}) : phi::make_ddim({first_dim[0]}); } else { out_dim = is_vector ? phi::make_ddim({last_dim[1]}) : phi::make_ddim({first_dim[0], last_dim[1]}); } auto width = first_dim[1]; for (size_t i = 1; i < n - 1; i++) { PADDLE_ENFORCE_EQ(inputs_dims[i].size(), static_cast(2), phi::errors::InvalidArgument( "the input tensor of multi_dot op must be 2D.")); const auto& tmp_dim = inputs_dims[i]; PADDLE_ENFORCE_EQ( tmp_dim[0], width, phi::errors::InvalidArgument( "the input matrix does not meet the multiplication requirements.")); width = tmp_dim[1]; } PADDLE_ENFORCE_EQ( last_dim[0], width, phi::errors::InvalidArgument( "the input matrix does not meet the multiplication requirements.")); out->set_dims(out_dim); out->set_dtype(x.at(0)->dtype()); out->share_lod(*x.at(0)); } void MultiplexInferMeta(const std::vector& ins, const MetaTensor& ids, MetaTensor* out) { PADDLE_ENFORCE_NE( ins.empty(), true, phi::errors::InvalidArgument("MultiInput(X) shouldn't be empty.")); auto ids_dim = ids.dims(); PADDLE_ENFORCE_EQ(ids_dim.size(), 2, phi::errors::PreconditionNotMet( "The index tensor must be a vector with 2 dimensions")); PADDLE_ENFORCE_EQ( ids_dim[1], 1, phi::errors::PreconditionNotMet( "The index tensor must be a vector with batchSize x 1.")); auto ins_dims = GetMetaTensorsDim(ins); auto num_ins = ins_dims.size(); PADDLE_ENFORCE_GT( num_ins, 1, phi::errors::InvalidArgument("multiplex operator should have more than " "one candidate input tensors.")); auto in_dim = ins_dims[0]; PADDLE_ENFORCE_GE( in_dim.size(), 2, phi::errors::InvalidArgument( "The rank of candidate tensors must be not less than 2.")); for (size_t i = 1; i < num_ins; i++) { auto dim = ins_dims[i]; PADDLE_ENFORCE_EQ( in_dim, dim, phi::errors::PreconditionNotMet( "All the candidate tensors must have the same size.")); } out->set_dims(in_dim); out->set_dtype(ins[0]->dtype()); } void PsroiPoolInferMeta(const MetaTensor& x, const MetaTensor& rois, paddle::optional rois_num, int pooled_height, int pooled_width, int output_channels, float spatial_scale, MetaTensor* out) { auto input_dims = x.dims(); auto rois_dims = rois.dims(); PADDLE_ENFORCE_EQ( input_dims.size(), 4, errors::InvalidArgument("The format of input tensor is NCHW")); PADDLE_ENFORCE_EQ(rois_dims.size(), 2, errors::InvalidArgument( "ROIs should be a 2-D LoDTensor of shape (num_rois, 4) " "given as [(x1, y1, x2, y2), ...]")); PADDLE_ENFORCE_EQ(rois_dims[1], 4, errors::InvalidArgument( "ROIs should be a 2-D LoDTensor of shape (num_rois, 4) " "given as [(x1, y1, x2, y2), ...]")); if (rois_num.get_ptr()) { auto rois_num_dims = rois_num->dims(); PADDLE_ENFORCE_EQ( rois_num_dims.size(), 1, errors::InvalidArgument("The second dimension of RoisNum should " "be 1, but received dimension is %d", rois_num_dims.size())); } PADDLE_ENFORCE_EQ( input_dims[1], output_channels * pooled_height * pooled_width, errors::InvalidArgument( "the channel of X(%d) " "should be equal to the product of " "output_channels(%d), pooled_height(%d) and pooled_width(%d)", input_dims[1], output_channels, pooled_height, pooled_width)); PADDLE_ENFORCE_GT(pooled_height, 0, errors::InvalidArgument( "The pooled output height must be greater than 0")); PADDLE_ENFORCE_GT(pooled_width, 0, errors::InvalidArgument( "The pooled output width must be greater than 0")); PADDLE_ENFORCE_GT(output_channels, 1, errors::InvalidArgument( "The pooled output channels must greater than 1")); PADDLE_ENFORCE_GT( spatial_scale, 0.0f, errors::InvalidArgument("The spatial scale must greater than 0.")); auto out_dims = input_dims; out_dims[0] = rois_dims[0]; out_dims[1] = output_channels; // input_dims[1] / (pooled_height * pooled_width); out_dims[2] = pooled_height; out_dims[3] = pooled_width; out->set_dims(out_dims); out->set_dtype(x.dtype()); } void RmspropInferMeta(const MetaTensor& param, const MetaTensor& mean_square, const MetaTensor& grad, const MetaTensor& moment, const MetaTensor& learning_rate, paddle::optional mean_grad, float epsilon, float decay, float momentum, bool centered, MetaTensor* param_out, MetaTensor* moment_out, MetaTensor* mean_square_out, MetaTensor* mean_grad_out) { if (centered) { PADDLE_ENFORCE_NOT_NULL( mean_grad_out, phi::errors::InvalidArgument( "Output(MeanGradOut) of RmspropOp should not be null.")); } auto param_dim = param.dims(); PADDLE_ENFORCE_EQ(param_dim, moment.dims(), phi::errors::InvalidArgument( "Param and Momentum input of RmspropOp " "should have the same dimension. But received " "Param's dim [%s] and Moment [%s]", param_dim, moment.dims())); PADDLE_ENFORCE_EQ(param_dim, mean_square.dims(), phi::errors::InvalidArgument( "Param and Momentum input of RmspropOp " "should have the same dimension. But received " "Param's dim [%s] and MeanSquare [%s]", param_dim, mean_square.dims())); auto lr_dim = learning_rate.dims(); PADDLE_ENFORCE_EQ(phi::product(lr_dim), 1, phi::errors::InvalidArgument( "Learning Rate of RmspropOp should be a scalar. But " "received LearningRate's dim [%s]", phi::product(lr_dim))); param_out->set_dims(param_dim); param_out->set_dtype(param.dtype()); moment_out->set_dims(param_dim); moment_out->set_dtype(moment.dtype()); mean_square_out->set_dims(param_dim); mean_square_out->set_dtype(mean_square.dtype()); if (centered) { mean_grad_out->set_dims(param_dim); mean_grad_out->set_dtype(mean_grad.get_ptr()->dtype()); } } void RnnInferMeta(const MetaTensor& x, const std::vector& pre_state, const std::vector& weight_list, paddle::optional sequence_length, float dropout_prob, bool is_bidirec, int input_size, int hidden_size, int num_layers, const std::string& mode, int seed, bool is_test, MetaTensor* out, MetaTensor* dropout_state, std::vector state, MetaTensor* reserve) { auto in_dims = x.dims(); PADDLE_ENFORCE_EQ( in_dims.size(), 3, phi::errors::InvalidArgument("The rank of Input in RNN must be 3. But " "received Input's rank is %d.", in_dims.size())); if (sequence_length) { auto seq_dims = sequence_length->dims(); PADDLE_ENFORCE_EQ( in_dims[1], seq_dims[0], phi::errors::InvalidArgument( "The size of SequenceLength has to equal the batch_size. But " "received batch_size is %d and the size of SequenceLength is %d.", in_dims[1], seq_dims[0])); } PADDLE_ENFORCE_EQ(pre_state[0]->dims().size(), 3, phi::errors::InvalidArgument( "The rank of PreState in RNN must be 3. But " "the received rank is %d.", pre_state[0]->dims().size())); size_t i = 0; for (; i < pre_state.size(); ++i) { PADDLE_ENFORCE_EQ( in_dims[1], pre_state[i]->dims()[1], phi::errors::InvalidArgument( "The second dimension size (representing for batch size) of " "Input and PreState should be equal. But received %d and %d.", in_dims[1], pre_state[i]->dims()[1])); PADDLE_ENFORCE_EQ( pre_state[0]->dims(), pre_state[i]->dims(), phi::errors::InvalidArgument( "The dims of all tensors in PreState should be same. But " "received PreState[0] is %s and PreState[%d] is %s.", pre_state[0]->dims(), i, pre_state[i]->dims())); } size_t num_state = mode == "LSTM" ? 2 : 1; PADDLE_ENFORCE_EQ(i, num_state, phi::errors::InvalidArgument( "The number of tensors in PreState of %s should be %d, " "but received %d.", mode, 2, i)); auto out_dims = in_dims; out_dims[2] = is_bidirec ? hidden_size * 2 : hidden_size; out->set_dims(out_dims); out->set_dtype(x.dtype()); int state_num = pre_state.size(); for (int i = 0; i < state_num; ++i) { state[i]->set_dims(pre_state[i]->dims()); state[i]->set_dtype(x.dtype()); } } void SGDInferMeta(const MetaTensor& param, const MetaTensor& learning_rate, const MetaTensor& grad, paddle::optional master_param, bool multi_precision, MetaTensor* param_out, MetaTensor* master_param_out) { PADDLE_ENFORCE_NOT_NULL(param_out, phi::errors::InvalidArgument( "Output(ParamOut) of SGDOp should not be null.")); auto lr_dims = learning_rate.dims(); PADDLE_ENFORCE_EQ(phi::product(lr_dims), 1, phi::errors::InvalidArgument( "Learning rate should have 1 element. But received " "LearningRate dims [%s]", phi::product(lr_dims))); param_out->set_dims(param.dims()); param_out->set_dtype(param.dtype()); } void StackInferMeta(const std::vector& x, int axis, MetaTensor* out) { PADDLE_ENFORCE_GT(x.size(), 0UL, phi::errors::InvalidArgument( "Number of Inputs(x) must be larger than 0, but" " received value is:%d.", x.size())); const auto& input_dims = GetMetaTensorsDim(x); for (size_t i = 1; i < input_dims.size(); ++i) { PADDLE_ENFORCE_EQ(input_dims[i], input_dims[0], phi::errors::InvalidArgument( "Dims of all Inputs(X) must be the same, but" " received input %d dim is:%d not equal to input 0" " dim:%d.", i, input_dims[i], input_dims[0])); } int rank = input_dims[0].size(); PADDLE_ENFORCE_GE( axis, -(rank + 1), phi::errors::InvalidArgument( "Attr(axis) must be inside [-(rank+1), rank+1), where rank = %d, " "but received axis is:%d.", rank, axis)); PADDLE_ENFORCE_LT( axis, rank + 1, phi::errors::InvalidArgument( "Attr(axis) must be inside [-(rank+1), rank+1), where rank = %d, " "but received axis is:%d", rank, axis)); if (axis < 0) axis += (rank + 1); auto vec = phi::vectorize(input_dims[0]); vec.insert(vec.begin() + axis, input_dims.size()); out->set_dims(phi::make_ddim(vec)); out->set_dtype(x.at(0)->dtype()); out->share_lod(*x.at(0)); } void UnchangedMultiInferMeta(const std::vector& x, std::vector out) { for (size_t i = 0; i < x.size(); ++i) { out[i]->share_meta(*x[i]); } } void WarpctcInferMeta(const MetaTensor& logits, const MetaTensor& label, const paddle::optional logits_length, const paddle::optional labels_length, int blank, bool norm_by_times, MetaTensor* warpctc_grad, MetaTensor* loss) { auto logits_dims = logits.dims(); int sequence_width = 0; if (logits_length.is_initialized()) { sequence_width = logits_dims[2]; } else { sequence_width = static_cast(phi::product(logits_dims) / logits_dims[0]); } PADDLE_ENFORCE_GE( blank, 0, errors::InvalidArgument( "The value of Attr(blank) should be in interval [0, %d), " "but received %d", blank)); PADDLE_ENFORCE_LT( blank, sequence_width, errors::InvalidArgument( "The value of Attr(blank) should be in interval [0, %d), " "but received %d", blank)); loss->set_dims({-1, 1}); loss->set_dtype(logits.dtype()); } void WhereInferMeta(const MetaTensor& condition, const MetaTensor& x, const MetaTensor& y, MetaTensor* out) { auto cond_dims = condition.dims(); auto x_dims = x.dims(); auto y_dims = y.dims(); PADDLE_ENFORCE_EQ( cond_dims, x_dims, phi::errors::InvalidArgument( "The dims of Inputs(Condition) and Inputs(X) should be same. " "But received Condition's shape is [%s], X's shape is [%s]", cond_dims, x_dims)); PADDLE_ENFORCE_EQ(x_dims, y_dims, phi::errors::InvalidArgument( "The dims of Inputs(X) and Inputs(Y) should be same. " "But received X's shape is [%s], Y's shape is [%s]", x_dims, y_dims)); out->share_meta(x); } void GraphReindexInferMeta(const MetaTensor& x, const MetaTensor& neighbors, const MetaTensor& count, paddle::optional hashtable_value, paddle::optional hashtable_index, bool flag_buffer_hashtable, MetaTensor* reindex_src, MetaTensor* reindex_dst, MetaTensor* out_nodes) { auto GraphReindexShapeCheck = [](const phi::DDim& dims, std::string tensor_name) { if (dims.size() == 2) { PADDLE_ENFORCE_EQ( dims[1], 1, phi::errors::InvalidArgument("The last dim of %s should be 1 when it " "is 2D, but we get %d", tensor_name, dims[1])); } else { PADDLE_ENFORCE_EQ( dims.size(), 1, phi::errors::InvalidArgument( "The %s should be 1D, when it is not 2D, but we get %d", tensor_name, dims.size())); } }; GraphReindexShapeCheck(x.dims(), "X"); GraphReindexShapeCheck(neighbors.dims(), "Neighbors"); GraphReindexShapeCheck(count.dims(), "Count"); if (flag_buffer_hashtable) { GraphReindexShapeCheck(hashtable_value->dims(), "HashTable_Value"); GraphReindexShapeCheck(hashtable_index->dims(), "HashTable_Index"); } reindex_src->set_dims({-1}); reindex_src->set_dtype(neighbors.dtype()); reindex_dst->set_dims({-1}); reindex_dst->set_dtype(neighbors.dtype()); out_nodes->set_dims({-1}); out_nodes->set_dtype(x.dtype()); } void GraphSampleNeighborsInferMeta( const MetaTensor& row, const MetaTensor& col_ptr, const MetaTensor& x, paddle::optional eids, paddle::optional perm_buffer, int sample_size, bool return_eids, bool flag_perm_buffer, MetaTensor* out, MetaTensor* out_count, MetaTensor* out_eids) { // GSN: GraphSampleNeighbors auto GSNShapeCheck = [](const phi::DDim& dims, std::string tensor_name) { if (dims.size() == 2) { PADDLE_ENFORCE_EQ( dims[1], 1, phi::errors::InvalidArgument("The last dim of %s should be 1 when it " "is 2D, but we get %d", tensor_name, dims[1])); } else { PADDLE_ENFORCE_EQ( dims.size(), 1, phi::errors::InvalidArgument( "The %s should be 1D, when it is not 2D, but we get %d", tensor_name, dims.size())); } }; GSNShapeCheck(row.dims(), "Row"); GSNShapeCheck(col_ptr.dims(), "Col_Ptr"); GSNShapeCheck(x.dims(), "X"); if (return_eids) { GSNShapeCheck(eids->dims(), "Eids"); out_eids->set_dims({-1}); out_eids->set_dtype(row.dtype()); } if (flag_perm_buffer) { GSNShapeCheck(perm_buffer->dims(), "Perm_Buffer"); } out->set_dims({-1}); out->set_dtype(row.dtype()); out_count->set_dims({-1}); out_count->set_dtype(DataType::INT32); } void Yolov3LossInferMeta(const MetaTensor& x, const MetaTensor& gt_box, const MetaTensor& gt_label, const paddle::optional gt_score, const std::vector& anchors, const std::vector& anchor_mask, int class_num, float ignore_thresh, int downsample_ratio, bool use_label_smooth, float scale_x_y, MetaTensor* loss, MetaTensor* objectness_mask, MetaTensor* gt_match_mask) { auto dim_x = x.dims(); auto dim_gtbox = gt_box.dims(); auto dim_gtlabel = gt_label.dims(); int anchor_num = anchors.size() / 2; int mask_num = anchor_mask.size(); PADDLE_ENFORCE_EQ(dim_x.size(), 4, phi::errors::InvalidArgument( "Input(X) should be a 4-D tensor. But received " "X dimension size(%s)", dim_x.size())); PADDLE_ENFORCE_EQ( dim_x[2], dim_x[3], phi::errors::InvalidArgument("Input(X) dim[3] and dim[4] should be euqal." "But received dim[3](%s) != dim[4](%s)", dim_x[2], dim_x[3])); PADDLE_ENFORCE_EQ( dim_x[1], mask_num * (5 + class_num), phi::errors::InvalidArgument( "Input(X) dim[1] should be equal to (anchor_mask_number * (5 " "+ class_num))." "But received dim[1](%s) != (anchor_mask_number * " "(5+class_num)(%s).", dim_x[1], mask_num * (5 + class_num))); PADDLE_ENFORCE_EQ( dim_gtbox.size(), 3, phi::errors::InvalidArgument("Input(GTBox) should be a 3-D tensor, but " "received gtbox dimension size(%s)", dim_gtbox.size())); PADDLE_ENFORCE_EQ( dim_gtbox[2], 4, phi::errors::InvalidArgument("Input(GTBox) dim[2] should be 4", "But receive dim[2](%s) != 5. ", dim_gtbox[2])); PADDLE_ENFORCE_EQ(dim_gtlabel.size(), 2, phi::errors::InvalidArgument( "Input(GTLabel) should be a 2-D tensor," "But received Input(GTLabel) dimension size(%s) != 2.", dim_gtlabel.size())); PADDLE_ENFORCE_EQ( dim_gtlabel[0], dim_gtbox[0], phi::errors::InvalidArgument( "Input(GTBox) dim[0] and Input(GTLabel) dim[0] should be same," "But received Input(GTLabel) dim[0](%s) != " "Input(GTBox) dim[0](%s)", dim_gtlabel[0], dim_gtbox[0])); PADDLE_ENFORCE_EQ( dim_gtlabel[1], dim_gtbox[1], phi::errors::InvalidArgument( "Input(GTBox) and Input(GTLabel) dim[1] should be same," "But received Input(GTBox) dim[1](%s) != Input(GTLabel) " "dim[1](%s)", dim_gtbox[1], dim_gtlabel[1])); PADDLE_ENFORCE_GT(anchors.size(), 0, phi::errors::InvalidArgument( "Attr(anchors) length should be greater then 0." "But received anchors length(%s)", anchors.size())); PADDLE_ENFORCE_EQ(anchors.size() % 2, 0, phi::errors::InvalidArgument( "Attr(anchors) length should be even integer." "But received anchors length(%s)", anchors.size())); for (size_t i = 0; i < anchor_mask.size(); i++) { PADDLE_ENFORCE_LT( anchor_mask[i], anchor_num, phi::errors::InvalidArgument( "Attr(anchor_mask) should not crossover Attr(anchors)." "But received anchor_mask[i](%s) > anchor_num(%s)", anchor_mask[i], anchor_num)); } PADDLE_ENFORCE_GT(class_num, 0, phi::errors::InvalidArgument( "Attr(class_num) should be an integer greater then 0." "But received class_num(%s) < 0", class_num)); if (gt_score.get_ptr()) { auto dim_gtscore = gt_score->dims(); PADDLE_ENFORCE_EQ( dim_gtscore.size(), 2, phi::errors::InvalidArgument("Input(GTScore) should be a 2-D tensor" "But received GTScore dimension(%s)", dim_gtbox.size())); PADDLE_ENFORCE_EQ( dim_gtscore[0], dim_gtbox[0], phi::errors::InvalidArgument( "Input(GTBox) and Input(GTScore) dim[0] should be same" "But received GTBox dim[0](%s) != GTScore dim[0](%s)", dim_gtbox[0], dim_gtscore[0])); PADDLE_ENFORCE_EQ( dim_gtscore[1], dim_gtbox[1], phi::errors::InvalidArgument( "Input(GTBox) and Input(GTScore) dim[1] should be same" "But received GTBox dim[1](%s) != GTScore dim[1](%s)", dim_gtscore[1], dim_gtbox[1])); } std::vector dim_out({dim_x[0]}); loss->set_dims(phi::make_ddim(dim_out)); loss->set_dtype(x.dtype()); std::vector dim_obj_mask({dim_x[0], mask_num, dim_x[2], dim_x[3]}); objectness_mask->set_dims(phi::make_ddim(dim_obj_mask)); objectness_mask->set_dtype(x.dtype()); std::vector dim_gt_match_mask({dim_gtbox[0], dim_gtbox[1]}); gt_match_mask->set_dims(phi::make_ddim(dim_gt_match_mask)); gt_match_mask->set_dtype(x.dtype()); } } // namespace phi PD_REGISTER_INFER_META_FN(batch_norm, phi::BatchNormInferMeta); PD_REGISTER_INFER_META_FN(batch_norm_infer, phi::BatchNormInferInferMeta);