Source code for torch_geometric.nn.models.autoencoder

import torch
from sklearn.metrics import roc_auc_score, average_precision_score
from torch_geometric.utils import (negative_sampling, remove_self_loops,
                                   add_self_loops)

from ..inits import reset

EPS = 1e-15
MAX_LOGVAR = 10


[docs]class InnerProductDecoder(torch.nn.Module): r"""The inner product decoder from the `"Variational Graph Auto-Encoders" <https://arxiv.org/abs/1611.07308>`_ paper .. math:: \sigma(\mathbf{Z}\mathbf{Z}^{\top}) where :math:`\mathbf{Z} \in \mathbb{R}^{N \times d}` denotes the latent space produced by the encoder."""
[docs] def forward(self, z, edge_index, sigmoid=True): r"""Decodes the latent variables :obj:`z` into edge probabilities for the given node-pairs :obj:`edge_index`. Args: z (Tensor): The latent space :math:`\mathbf{Z}`. sigmoid (bool, optional): If set to :obj:`False`, does not apply the logistic sigmoid function to the output. (default: :obj:`True`) """ value = (z[edge_index[0]] * z[edge_index[1]]).sum(dim=1) return torch.sigmoid(value) if sigmoid else value
[docs] def forward_all(self, z, sigmoid=True): r"""Decodes the latent variables :obj:`z` into a probabilistic dense adjacency matrix. Args: z (Tensor): The latent space :math:`\mathbf{Z}`. sigmoid (bool, optional): If set to :obj:`False`, does not apply the logistic sigmoid function to the output. (default: :obj:`True`) """ adj = torch.matmul(z, z.t()) return torch.sigmoid(adj) if sigmoid else adj
[docs]class GAE(torch.nn.Module): r"""The Graph Auto-Encoder model from the `"Variational Graph Auto-Encoders" <https://arxiv.org/abs/1611.07308>`_ paper based on user-defined encoder and decoder models. Args: encoder (Module): The encoder module. decoder (Module, optional): The decoder module. If set to :obj:`None`, will default to the :class:`torch_geometric.nn.models.InnerProductDecoder`. (default: :obj:`None`) """ def __init__(self, encoder, decoder=None): super(GAE, self).__init__() self.encoder = encoder self.decoder = InnerProductDecoder() if decoder is None else decoder GAE.reset_parameters(self)
[docs] def reset_parameters(self): reset(self.encoder) reset(self.decoder)
[docs] def encode(self, *args, **kwargs): r"""Runs the encoder and computes node-wise latent variables.""" return self.encoder(*args, **kwargs)
[docs] def decode(self, *args, **kwargs): r"""Runs the decoder and computes edge probabilities.""" return self.decoder(*args, **kwargs)
[docs] def recon_loss(self, z, pos_edge_index): r"""Given latent variables :obj:`z`, computes the binary cross entropy loss for positive edges :obj:`pos_edge_index` and negative sampled edges. Args: z (Tensor): The latent space :math:`\mathbf{Z}`. pos_edge_index (LongTensor): The positive edges to train against. """ pos_loss = -torch.log( self.decoder(z, pos_edge_index, sigmoid=True) + EPS).mean() # Do not include self-loops in negative samples pos_edge_index, _ = remove_self_loops(pos_edge_index) pos_edge_index, _ = add_self_loops(pos_edge_index) neg_edge_index = negative_sampling(pos_edge_index, z.size(0)) neg_loss = -torch.log(1 - self.decoder(z, neg_edge_index, sigmoid=True) + EPS).mean() return pos_loss + neg_loss
[docs] def test(self, z, pos_edge_index, neg_edge_index): r"""Given latent variables :obj:`z`, positive edges :obj:`pos_edge_index` and negative edges :obj:`neg_edge_index`, computes area under the ROC curve (AUC) and average precision (AP) scores. Args: z (Tensor): The latent space :math:`\mathbf{Z}`. pos_edge_index (LongTensor): The positive edges to evaluate against. neg_edge_index (LongTensor): The negative edges to evaluate against. """ pos_y = z.new_ones(pos_edge_index.size(1)) neg_y = z.new_zeros(neg_edge_index.size(1)) y = torch.cat([pos_y, neg_y], dim=0) pos_pred = self.decoder(z, pos_edge_index, sigmoid=True) neg_pred = self.decoder(z, neg_edge_index, sigmoid=True) pred = torch.cat([pos_pred, neg_pred], dim=0) y, pred = y.detach().cpu().numpy(), pred.detach().cpu().numpy() return roc_auc_score(y, pred), average_precision_score(y, pred)
[docs]class VGAE(GAE): r"""The Variational Graph Auto-Encoder model from the `"Variational Graph Auto-Encoders" <https://arxiv.org/abs/1611.07308>`_ paper. Args: encoder (Module): The encoder module to compute :math:`\mu` and :math:`\log\sigma^2`. decoder (Module, optional): The decoder module. If set to :obj:`None`, will default to the :class:`torch_geometric.nn.models.InnerProductDecoder`. (default: :obj:`None`) """ def __init__(self, encoder, decoder=None): super(VGAE, self).__init__(encoder, decoder)
[docs] def reparametrize(self, mu, logvar): if self.training: return mu + torch.randn_like(logvar) * torch.exp(logvar) else: return mu
[docs] def encode(self, *args, **kwargs): """""" self.__mu__, self.__logvar__ = self.encoder(*args, **kwargs) self.__logvar__ = self.__logvar__.clamp(max=MAX_LOGVAR) z = self.reparametrize(self.__mu__, self.__logvar__) return z
[docs] def kl_loss(self, mu=None, logvar=None): r"""Computes the KL loss, either for the passed arguments :obj:`mu` and :obj:`logvar`, or based on latent variables from last encoding. Args: mu (Tensor, optional): The latent space for :math:`\mu`. If set to :obj:`None`, uses the last computation of :math:`mu`. (default: :obj:`None`) logvar (Tensor, optional): The latent space for :math:`\log\sigma^2`. If set to :obj:`None`, uses the last computation of :math:`\log\sigma^2`.(default: :obj:`None`) """ mu = self.__mu__ if mu is None else mu logvar = self.__logvar__ if logvar is None else logvar.clamp( max=MAX_LOGVAR) return -0.5 * torch.mean( torch.sum(1 + logvar - mu**2 - logvar.exp(), dim=1))
[docs]class ARGA(GAE): r"""The Adversarially Regularized Graph Auto-Encoder model from the `"Adversarially Regularized Graph Autoencoder for Graph Embedding" <https://arxiv.org/abs/1802.04407>`_ paper. paper. Args: encoder (Module): The encoder module. discriminator (Module): The discriminator module. decoder (Module, optional): The decoder module. If set to :obj:`None`, will default to the :class:`torch_geometric.nn.models.InnerProductDecoder`. (default: :obj:`None`) """ def __init__(self, encoder, discriminator, decoder=None): super(ARGA, self).__init__(encoder, decoder) self.discriminator = discriminator reset(self.discriminator)
[docs] def reset_parameters(self): super(ARGA, self).reset_parameters() reset(self.discriminator)
[docs] def reg_loss(self, z): r"""Computes the regularization loss of the encoder. Args: z (Tensor): The latent space :math:`\mathbf{Z}`. """ real = torch.sigmoid(self.discriminator(z)) real_loss = -torch.log(real + EPS).mean() return real_loss
[docs] def discriminator_loss(self, z): r"""Computes the loss of the discriminator. Args: z (Tensor): The latent space :math:`\mathbf{Z}`. """ real = torch.sigmoid(self.discriminator(torch.randn_like(z))) fake = torch.sigmoid(self.discriminator(z.detach())) real_loss = -torch.log(real + EPS).mean() fake_loss = -torch.log(1 - fake + EPS).mean() return real_loss + fake_loss
[docs]class ARGVA(ARGA): r"""The Adversarially Regularized Variational Graph Auto-Encoder model from the `"Adversarially Regularized Graph Autoencoder for Graph Embedding" <https://arxiv.org/abs/1802.04407>`_ paper. paper. Args: encoder (Module): The encoder module to compute :math:`\mu` and :math:`\log\sigma^2`. discriminator (Module): The discriminator module. decoder (Module, optional): The decoder module. If set to :obj:`None`, will default to the :class:`torch_geometric.nn.models.InnerProductDecoder`. (default: :obj:`None`) """ def __init__(self, encoder, discriminator, decoder=None): super(ARGVA, self).__init__(encoder, discriminator, decoder) self.VGAE = VGAE(encoder, decoder) @property def __mu__(self): return self.VGAE.__mu__ @property def __logvar__(self): return self.VGAE.__logvar__
[docs] def reparametrize(self, mu, logvar): return self.VGAE.reparametrize(mu, logvar)
[docs] def encode(self, *args, **kwargs): """""" return self.VGAE.encode(*args, **kwargs)
[docs] def kl_loss(self, mu=None, logvar=None): return self.VGAE.kl_loss(mu, logvar)