IF YOU WOULD LIKE TO GET AN ACCOUNT, please write an email to s dot adaszewski at gmail dot com. User accounts are meant only to report issues and/or generate pull requests. This is a purpose-specific Git hosting for ADARED projects. Thank you for your understanding!
sadaszewski1
/
decagon-pytorch
feito fork de sadaszewski/decagon-pytorch
1
0
Fork 0
Código Issues 0 Pull requests 0 Versões 0 Wiki Atividade
Você não pode selecionar mais de 25 tópicos Os tópicos devem começar com uma letra ou um número, podem incluir traços ('-') e podem ter até 35 caracteres.
50 Commits
1 Branch
866KB
Tag: c1689b4985
Branches Tags
${ item.name }
Criar branch ${ searchTerm }
de c1689b4985
${ noResults }
decagon-pytorch/src/decagon_pytorch/decode/pairwise.py

124 linhas
4.4KB
Original Anotar Histórico 

  1. #

  2. # Copyright (C) Stanislaw Adaszewski, 2020

  3. # License: GPLv3

  4. #

  5. 

  6. 

  7. import torch

  8. from ..weights import init_glorot

  9. from ..dropout import dropout

  10. 

  11. 

  12. class DEDICOMDecoder(torch.nn.Module):

  13.     """DEDICOM Tensor Factorization Decoder model layer for link prediction."""

  14.     def __init__(self, input_dim, num_relation_types, drop_prob=0.,

  15.         activation=torch.sigmoid, **kwargs):

  16. 

  17.         super().__init__(**kwargs)

  18.         self.input_dim = input_dim

  19.         self.num_relation_types = num_relation_types

  20.         self.drop_prob = drop_prob

  21.         self.activation = activation

  22. 

  23.         self.global_interaction = init_glorot(input_dim, input_dim)

  24.         self.local_variation = [

  25.             torch.flatten(init_glorot(input_dim, 1)) \

  26.                 for _ in range(num_relation_types)

  27.         ]

  28. 

  29.     def forward(self, inputs_row, inputs_col):

  30.         outputs = []

  31.         for k in range(self.num_relation_types):

  32.             inputs_row = dropout(inputs_row, 1.-self.drop_prob)

  33.             inputs_col = dropout(inputs_col, 1.-self.drop_prob)

  34. 

  35.             relation = torch.diag(self.local_variation[k])

  36. 

  37.             product1 = torch.mm(inputs_row, relation)

  38.             product2 = torch.mm(product1, self.global_interaction)

  39.             product3 = torch.mm(product2, relation)

  40.             rec = torch.mm(product3, torch.transpose(inputs_col, 0, 1))

  41.             outputs.append(self.activation(rec))

  42.         return outputs

  43. 

  44. 

  45. class DistMultDecoder(torch.nn.Module):

  46.     """DEDICOM Tensor Factorization Decoder model layer for link prediction."""

  47.     def __init__(self, input_dim, num_relation_types, drop_prob=0.,

  48.         activation=torch.sigmoid, **kwargs):

  49. 

  50.         super().__init__(**kwargs)

  51.         self.input_dim = input_dim

  52.         self.num_relation_types = num_relation_types

  53.         self.drop_prob = drop_prob

  54.         self.activation = activation

  55. 

  56.         self.relation = [

  57.             torch.flatten(init_glorot(input_dim, 1)) \

  58.                 for _ in range(num_relation_types)

  59.         ]

  60. 

  61.     def forward(self, inputs_row, inputs_col):

  62.         outputs = []

  63.         for k in range(self.num_relation_types):

  64.             inputs_row = dropout(inputs_row, 1.-self.drop_prob)

  65.             inputs_col = dropout(inputs_col, 1.-self.drop_prob)

  66. 

  67.             relation = torch.diag(self.relation[k])

  68. 

  69.             intermediate_product = torch.mm(inputs_row, relation)

  70.             rec = torch.mm(intermediate_product, torch.transpose(inputs_col, 0, 1))

  71.             outputs.append(self.activation(rec))

  72.         return outputs

  73. 

  74. 

  75. class BilinearDecoder(torch.nn.Module):

  76.     """DEDICOM Tensor Factorization Decoder model layer for link prediction."""

  77.     def __init__(self, input_dim, num_relation_types, drop_prob=0.,

  78.         activation=torch.sigmoid, **kwargs):

  79. 

  80.         super().__init__(**kwargs)

  81.         self.input_dim = input_dim

  82.         self.num_relation_types = num_relation_types

  83.         self.drop_prob = drop_prob

  84.         self.activation = activation

  85. 

  86.         self.relation = [

  87.             init_glorot(input_dim, input_dim) \

  88.                 for _ in range(num_relation_types)

  89.         ]

  90. 

  91.     def forward(self, inputs_row, inputs_col):

  92.         outputs = []

  93.         for k in range(self.num_relation_types):

  94.             inputs_row = dropout(inputs_row, 1.-self.drop_prob)

  95.             inputs_col = dropout(inputs_col, 1.-self.drop_prob)

  96. 

  97.             intermediate_product = torch.mm(inputs_row, self.relation[k])

  98.             rec = torch.mm(intermediate_product, torch.transpose(inputs_col, 0, 1))

  99.             outputs.append(self.activation(rec))

  100.         return outputs

  101. 

  102. 

  103. class InnerProductDecoder(torch.nn.Module):

  104.     """DEDICOM Tensor Factorization Decoder model layer for link prediction."""

  105.     def __init__(self, input_dim, num_relation_types, drop_prob=0.,

  106.         activation=torch.sigmoid, **kwargs):

  107. 

  108.         super().__init__(**kwargs)

  109.         self.input_dim = input_dim

  110.         self.num_relation_types = num_relation_types

  111.         self.drop_prob = drop_prob

  112.         self.activation = activation

  113. 

  114. 

  115.     def forward(self, inputs_row, inputs_col):

  116.         outputs = []

  117.         for k in range(self.num_relation_types):

  118.             inputs_row = dropout(inputs_row, 1.-self.drop_prob)

  119.             inputs_col = dropout(inputs_col, 1.-self.drop_prob)

  120. 

  121.             rec = torch.mm(inputs_row, torch.transpose(inputs_col, 0, 1))

  122.             outputs.append(self.activation(rec))

  123.         return outputs