nni.nas.hub.pytorch.modules.nasbench201 源代码

# Copyright (c) Microsoft Corporation.
# Licensed under the MIT license.

__all__ = ['NasBench201Cell']

from collections import OrderedDict
from typing import Callable, List, Dict, Union, Optional

import torch
import torch.nn as nn

from nni.mutable import label_scope
from nni.nas.nn.pytorch import LayerChoice, MutableModule

[文档] class NasBench201Cell(MutableModule): """ Cell structure that is proposed in NAS-Bench-201. Proposed by `NAS-Bench-201: Extending the Scope of Reproducible Neural Architecture Search <https://arxiv.org/abs/2001.00326>`__. This cell is a densely connected DAG with ``num_tensors`` nodes, where each node is tensor. For every :math:`i < j`, there is an edge from i-th node to j-th node. Each edge in this DAG is associated with an operation transforming the hidden state from the source node to the target node. All possible operations are selected from a predefined operation set, defined in ``op_candidates``. Each of the ``op_candidates`` should be a callable that accepts input dimension and output dimension, and returns a ``Module``. Input of this cell should be of shape :math:`[N, C_{in}, *]`, while output should be :math:`[N, C_{out}, *]`. For example, The space size of this cell would be :math:`|op|^{N(N-1)/2}`, where :math:`|op|` is the number of operation candidates, and :math:`N` is defined by ``num_tensors``. Parameters ---------- op_candidates : list of callable Operation candidates. Each should be a function accepts input feature and output feature, returning nn.Module. in_features : int Input dimension of cell. out_features : int Output dimension of cell. num_tensors : int Number of tensors in the cell (input included). Default: 4 label : str Identifier of the cell. Cell sharing the same label will semantically share the same choice. """ @staticmethod def _make_dict(x): if isinstance(x, list): return OrderedDict([(str(i), t) for i, t in enumerate(x)]) return OrderedDict(x) def __init__(self, op_candidates: Union[Dict[str, Callable[[int, int], nn.Module]], List[Callable[[int, int], nn.Module]]], in_features: int, out_features: int, num_tensors: int = 4, label: Optional[str] = None): super().__init__() self.layers = nn.ModuleList() self.in_features = in_features self.out_features = out_features self.num_tensors = num_tensors op_candidates = self._make_dict(op_candidates) with label_scope(label) as self._scope: for tid in range(1, num_tensors): node_ops = nn.ModuleList() for j in range(tid): inp = in_features if j == 0 else out_features op_choices = OrderedDict([(key, cls(inp, out_features)) for key, cls in op_candidates.items()]) node_ops.append(LayerChoice(op_choices, label=f'{j}_{tid}')) self.layers.append(node_ops) @torch.jit.unused @property def label(self) -> str: return self._scope.name def forward(self, inputs: torch.Tensor) -> torch.Tensor: tensors: List[torch.Tensor] = [inputs] for layer in self.layers: current_tensor: List[torch.Tensor] = [] for i, op in enumerate(layer): # type: ignore current_tensor.append(op(tensors[i])) # type: ignore tensors.append(torch.sum(torch.stack(current_tensor), 0)) return tensors[-1]