# 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. import unittest from functools import partial from typing import Any, Dict, List import numpy as np from program_config import ProgramConfig, TensorConfig from trt_layer_auto_scan_test import TrtLayerAutoScanTest import paddle.inference as paddle_infer class TrtConvertExpandV2Test(TrtLayerAutoScanTest): def is_program_valid(self, program_config: ProgramConfig) -> bool: if self.dtype in [0, 1, 4]: return False if self.dims != 4 and self.dtype != 2: return False return True def sample_program_configs(self): def generate_input1(attrs: List[Dict[str, Any]]): if self.dims == 4: self.input_shape = [1, 1, 4, 6] if self.dtype == 0: return np.random.random([1, 1, 4, 6]).astype(np.bool_) elif self.dtype == 1: return np.random.random([1, 1, 4, 6]).astype(np.int16) elif self.dtype == 2: return np.random.random([1, 1, 4, 6]).astype(np.int32) elif self.dtype == 3: return np.random.random([1, 1, 4, 6]).astype(np.int64) elif self.dtype == 4: return np.random.random([1, 1, 4, 6]).astype(np.float16) elif self.dtype == 5: return np.random.random([1, 1, 4, 6]).astype(np.float32) elif self.dtype == 6: return np.random.random([1, 1, 4, 6]).astype(np.float64) else: return np.random.random([1, 1, 4, 6]).astype(np.int32) elif self.dims == 3: self.input_shape = [1, 8, 6] return np.random.random([1, 8, 6]).astype(np.int32) elif self.dims == 2: self.input_shape = [1, 48] return np.random.random([1, 48]).astype(np.int32) elif self.dims == 1: self.input_shape = [48] return np.random.random([48]).astype(np.int32) def generate_weight1(attrs: List[Dict[str, Any]]): return np.array([1, 48]).astype(np.int32) def generate_shapeT1_data(attrs: List[Dict[str, Any]]): return np.array([2]).astype(np.int32) def generate_shapeT2_data(attrs: List[Dict[str, Any]]): return np.array([24]).astype(np.int32) for dims in [1, 2, 3, 4]: for value in [2]: for dtype in [-1, 0, 1, 2, 3, 4, 5, 6]: dics = [ { "value": value, "dtype": dtype, }, ] self.dims = dims self.dtype = dtype dics_intput = [{"X": ["fill_any_like_input"]}] ops_config = [ { "op_type": "fill_any_like", "op_inputs": dics_intput[0], "op_outputs": {"Out": ["fill_any_like_out"]}, "op_attrs": dics[0], } ] ops = self.generate_op_config(ops_config) program_config = ProgramConfig( ops=ops, weights={}, inputs={ "fill_any_like_input": TensorConfig( data_gen=partial(generate_input1, dics) ) }, outputs=["fill_any_like_out"], ) yield program_config def sample_predictor_configs( self, program_config ) -> (paddle_infer.Config, List[int], int): def generate_dynamic_shape(attrs): if self.dims == 4: self.dynamic_shape.min_input_shape = { "fill_any_like_input": [1, 1, 4, 6] } self.dynamic_shape.max_input_shape = { "fill_any_like_input": [10, 1, 4, 6] } self.dynamic_shape.opt_input_shape = { "fill_any_like_input": [1, 1, 4, 6] } elif self.dims == 3: self.dynamic_shape.min_input_shape = { "fill_any_like_input": [1, 8, 6] } self.dynamic_shape.max_input_shape = { "fill_any_like_input": [4, 8, 6] } self.dynamic_shape.opt_input_shape = { "fill_any_like_input": [1, 8, 6] } elif self.dims == 2: self.dynamic_shape.min_input_shape = { "fill_any_like_input": [1, 48] } self.dynamic_shape.max_input_shape = { "fill_any_like_input": [4, 48] } self.dynamic_shape.opt_input_shape = { "fill_any_like_input": [1, 48] } elif self.dims == 1: self.dynamic_shape.min_input_shape = { "fill_any_like_input": [48] } self.dynamic_shape.max_input_shape = { "fill_any_like_input": [48] } self.dynamic_shape.opt_input_shape = { "fill_any_like_input": [48] } def clear_dynamic_shape(): self.dynamic_shape.min_input_shape = {} self.dynamic_shape.max_input_shape = {} self.dynamic_shape.opt_input_shape = {} def generate_trt_nodes_num(attrs, dynamic_shape): if not dynamic_shape: return 0, 3 else: return 1, 2 attrs = [ program_config.ops[i].attrs for i in range(len(program_config.ops)) ] clear_dynamic_shape() self.trt_param.precision = paddle_infer.PrecisionType.Float32 program_config.set_input_type(np.float32) yield self.create_inference_config(), generate_trt_nodes_num( attrs, False ), 1e-5 self.trt_param.precision = paddle_infer.PrecisionType.Half program_config.set_input_type(np.float16) yield self.create_inference_config(), generate_trt_nodes_num( attrs, False ), 1e-5 # for dynamic_shape generate_dynamic_shape(attrs) self.trt_param.precision = paddle_infer.PrecisionType.Float32 program_config.set_input_type(np.float32) yield self.create_inference_config(), generate_trt_nodes_num( attrs, True ), 1e-5 self.trt_param.precision = paddle_infer.PrecisionType.Half program_config.set_input_type(np.float16) yield self.create_inference_config(), generate_trt_nodes_num( attrs, True ), 1e-5 def add_skip_trt_case(self): pass def test(self): self.add_skip_trt_case() self.run_test() if __name__ == "__main__": unittest.main()