diff --git a/paddle/fluid/inference/tensorrt/convert/flatten_contiguous_range_op.cc b/paddle/fluid/inference/tensorrt/convert/flatten_contiguous_range_op.cc index 706814340a0e9c06dfa11dd68500ceca040cbf00..e08f50833ed991f162dc232818427b97fa6bcd4f 100644 --- a/paddle/fluid/inference/tensorrt/convert/flatten_contiguous_range_op.cc +++ b/paddle/fluid/inference/tensorrt/convert/flatten_contiguous_range_op.cc @@ -30,14 +30,17 @@ class FlattenContiguousRangeOpConverter : public OpConverter { public: void operator()(const framework::proto::OpDesc& op, const framework::Scope& scope, bool test_mode) override { + VLOG(3) << "convert a fluid flatten_contiguous_range op to tensorrt layer"; framework::OpDesc op_desc(op, nullptr); // Declare inputs auto* input = engine_->GetITensor(op_desc.Input("X")[0]); - int dims = input->getDimensions().nbDims; + const auto input_dim = input->getDimensions(); + const int dims = input_dim.nbDims; int start_axis = BOOST_GET_CONST(int, op_desc.GetAttr("start_axis")); int stop_axis = BOOST_GET_CONST(int, op_desc.GetAttr("stop_axis")); - nvinfer1::IShuffleLayer* layer = nullptr; + nvinfer1::IShuffleLayer* layer = + TRT_ENGINE_ADD_LAYER(engine_, Shuffle, *input); if (!engine_->with_dynamic_shape()) { if (start_axis < 0) start_axis += dims + 1; if (stop_axis < 0) stop_axis += dims + 1; @@ -46,7 +49,7 @@ class FlattenContiguousRangeOpConverter : public OpConverter { flatten_dim.nbDims = dims - (stop_axis - start_axis); for (int i = 0, j = 0; i < dims; ++i) { if (start_axis <= i + 1 && i + 1 <= stop_axis) { - int dim_i = input->getDimensions().d[i]; + int dim_i = input_dim.d[i]; PADDLE_ENFORCE_GT(dim_i, 0, platform::errors::InvalidArgument( "flatten_contiguous_range input dim " "should be > 0, but got %d.", @@ -56,72 +59,103 @@ class FlattenContiguousRangeOpConverter : public OpConverter { flatten_dim.d[j++] = dim_prod; } } else { - flatten_dim.d[j++] = input->getDimensions().d[i]; + flatten_dim.d[j++] = input_dim.d[i]; } } - layer = TRT_ENGINE_ADD_LAYER(engine_, Shuffle, *input); layer->setReshapeDimensions(flatten_dim); } else { if (start_axis < 0) start_axis += dims; if (stop_axis < 0) stop_axis += dims; - auto* shape_layer = TRT_ENGINE_ADD_LAYER(engine_, Shape, *input); - auto* shape_layer_itensor = shape_layer->getOutput(0); - nvinfer1::Dims start_dim, size_dim, stride_dim; - start_dim.nbDims = 1; - size_dim.nbDims = 1; - stride_dim.nbDims = 1; - start_dim.d[0] = start_axis; - size_dim.d[0] = stop_axis - start_axis + 1; - stride_dim.d[0] = 1; - auto* slice_layer = - TRT_ENGINE_ADD_LAYER(engine_, Slice, *shape_layer_itensor, start_dim, - size_dim, stride_dim); - uint32_t reduce_dim = 1; - auto* reduce_prod_layer = TRT_ENGINE_ADD_LAYER( - engine_, Reduce, *(slice_layer->getOutput(0)), - nvinfer1::ReduceOperation::kPROD, reduce_dim, true); - - nvinfer1::ITensor* input_shape = nullptr; - if (start_axis == 0 && stop_axis == dims - 1) { - input_shape = reduce_prod_layer->getOutput(0); - } else { - std::vector itensors; - if (start_axis > 0) { - nvinfer1::Dims left_start_dim, left_size_dim, left_stride_dim; - left_start_dim.nbDims = 1; - left_size_dim.nbDims = 1; - left_stride_dim.nbDims = 1; - left_start_dim.d[0] = 0; - left_size_dim.d[0] = start_axis; - left_stride_dim.d[0] = 1; - auto* slice_layer_left = TRT_ENGINE_ADD_LAYER( - engine_, Slice, *shape_layer_itensor, left_start_dim, - left_size_dim, left_stride_dim); - itensors.push_back(slice_layer_left->getOutput(0)); + int dim_prod = 1; + int dim_negative = 0; + nvinfer1::Dims flatten_dim; + flatten_dim.nbDims = dims - (stop_axis - start_axis); + bool need_slice = false; + for (int i = 0, j = 0; i < dims; ++i) { + int dim_i = input_dim.d[i]; + if (start_axis <= i && i <= stop_axis) { + if (dim_i < 0) { + need_slice = true; + break; + } + dim_prod *= dim_i; + if (i == stop_axis) { + flatten_dim.d[j++] = dim_prod; + } + } else { + if (dim_i < 0) dim_negative++; + if (dim_negative > 1) { + need_slice = true; + break; + } + flatten_dim.d[j++] = input_dim.d[i]; } - itensors.push_back(reduce_prod_layer->getOutput(0)); - if (stop_axis < dims - 1) { - nvinfer1::Dims right_start_dim, right_size_dim, right_stride_dim; - right_start_dim.nbDims = 1; - right_size_dim.nbDims = 1; - right_stride_dim.nbDims = 1; - right_start_dim.d[0] = stop_axis + 1; - right_size_dim.d[0] = dims - stop_axis - 1; - right_stride_dim.d[0] = 1; - auto* slice_layer_right = TRT_ENGINE_ADD_LAYER( - engine_, Slice, *shape_layer_itensor, right_start_dim, - right_size_dim, right_stride_dim); - itensors.push_back(slice_layer_right->getOutput(0)); + } + + if (need_slice) { + VLOG(3) << "slice input dim when the input dimension has -1"; + auto* shape_layer = TRT_ENGINE_ADD_LAYER(engine_, Shape, *input); + auto* shape_layer_itensor = shape_layer->getOutput(0); + + nvinfer1::Dims start_dim, size_dim, stride_dim; + start_dim.nbDims = 1; + size_dim.nbDims = 1; + stride_dim.nbDims = 1; + start_dim.d[0] = start_axis; + size_dim.d[0] = stop_axis - start_axis + 1; + stride_dim.d[0] = 1; + auto* slice_layer = + TRT_ENGINE_ADD_LAYER(engine_, Slice, *shape_layer_itensor, + start_dim, size_dim, stride_dim); + uint32_t reduce_dim = 1; + auto* reduce_prod_layer = TRT_ENGINE_ADD_LAYER( + engine_, Reduce, *(slice_layer->getOutput(0)), + nvinfer1::ReduceOperation::kPROD, reduce_dim, true); + + nvinfer1::ITensor* input_shape = nullptr; + if (start_axis == 0 && stop_axis == dims - 1) { + input_shape = reduce_prod_layer->getOutput(0); + } else { + std::vector itensors; + if (start_axis > 0) { + nvinfer1::Dims left_start_dim, left_size_dim, left_stride_dim; + left_start_dim.nbDims = 1; + left_size_dim.nbDims = 1; + left_stride_dim.nbDims = 1; + left_start_dim.d[0] = 0; + left_size_dim.d[0] = start_axis; + left_stride_dim.d[0] = 1; + auto* slice_layer_left = TRT_ENGINE_ADD_LAYER( + engine_, Slice, *shape_layer_itensor, left_start_dim, + left_size_dim, left_stride_dim); + itensors.push_back(slice_layer_left->getOutput(0)); + } + itensors.push_back(reduce_prod_layer->getOutput(0)); + if (stop_axis < dims - 1) { + nvinfer1::Dims right_start_dim, right_size_dim, right_stride_dim; + right_start_dim.nbDims = 1; + right_size_dim.nbDims = 1; + right_stride_dim.nbDims = 1; + right_start_dim.d[0] = stop_axis + 1; + right_size_dim.d[0] = dims - stop_axis - 1; + right_stride_dim.d[0] = 1; + auto* slice_layer_right = TRT_ENGINE_ADD_LAYER( + engine_, Slice, *shape_layer_itensor, right_start_dim, + right_size_dim, right_stride_dim); + itensors.push_back(slice_layer_right->getOutput(0)); + } + auto* concat_layer = TRT_ENGINE_ADD_LAYER( + engine_, Concatenation, itensors.data(), itensors.size()); + concat_layer->setAxis(0); + input_shape = concat_layer->getOutput(0); } - auto* concat_layer = TRT_ENGINE_ADD_LAYER( - engine_, Concatenation, itensors.data(), itensors.size()); - concat_layer->setAxis(0); - input_shape = concat_layer->getOutput(0); + layer->setInput(1, *input_shape); + } else { + layer->setReshapeDimensions(flatten_dim); } - layer = TRT_ENGINE_ADD_LAYER(engine_, Shuffle, *input); - layer->setInput(1, *input_shape); } + auto output_name = op_desc.Output("Out")[0]; RreplenishLayerAndOutput(layer, "flatten_contiguous_range", {output_name}, test_mode);