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- from icosagon.input import InputLayer, \
- OneHotInputLayer
- from icosagon.data import Data
- import torch
- import pytest
-
-
- def _some_data():
- d = Data()
- d.add_node_type('Gene', 1000)
- d.add_node_type('Drug', 100)
-
- fam = d.add_relation_family('Drug-Gene', 1, 0, False)
- fam.add_relation_type('Target', torch.rand(100, 1000))
-
- fam = d.add_relation_family('Gene-Gene', 0, 0, False)
- fam.add_relation_type('Interaction', torch.rand(1000, 1000))
-
- fam = d.add_relation_family('Drug-Drug', 1, 1, False)
- fam.add_relation_type('Side Effect: Nausea', torch.rand(100, 100))
- fam.add_relation_type('Side Effect: Infertility', torch.rand(100, 100))
- fam.add_relation_type('Side Effect: Death', torch.rand(100, 100))
- return d
-
-
- def test_input_layer_01():
- d = _some_data()
- for output_dim in [32, 64, 128]:
- layer = InputLayer(d, output_dim)
- assert layer.output_dim[0] == output_dim
- assert len(layer.node_reps) == 2
- assert layer.node_reps[0].shape == (1000, output_dim)
- assert layer.node_reps[1].shape == (100, output_dim)
- assert layer.data == d
-
-
- def test_input_layer_02():
- d = _some_data()
- layer = InputLayer(d, 32)
- res = layer(None)
- assert isinstance(res[0], torch.Tensor)
- assert isinstance(res[1], torch.Tensor)
- assert res[0].shape == (1000, 32)
- assert res[1].shape == (100, 32)
- assert torch.all(res[0] == layer.node_reps[0])
- assert torch.all(res[1] == layer.node_reps[1])
-
-
- def test_input_layer_03():
- if torch.cuda.device_count() == 0:
- pytest.skip('No CUDA devices on this host')
- d = _some_data()
- layer = InputLayer(d, 32)
- device = torch.device('cuda:0')
- layer = layer.to(device)
- print(list(layer.parameters()))
- # assert layer.device.type == 'cuda:0'
- assert layer.node_reps[0].device == device
- assert layer.node_reps[1].device == device
-
-
- def test_input_layer_04():
- d = _some_data()
- layer = InputLayer(d, 32)
- s = repr(layer)
- assert s.startswith('Icosagon input layer')
-
-
- def test_one_hot_input_layer_01():
- d = _some_data()
- layer = OneHotInputLayer(d)
- assert layer.output_dim == [1000, 100]
- assert len(layer.node_reps) == 2
- assert layer.node_reps[0].shape == (1000, 1000)
- assert layer.node_reps[1].shape == (100, 100)
- assert layer.data == d
- assert layer.is_sparse
-
-
- def test_one_hot_input_layer_02():
- d = _some_data()
- layer = OneHotInputLayer(d)
- res = layer(None)
- assert isinstance(res[0], torch.Tensor)
- assert isinstance(res[1], torch.Tensor)
- assert res[0].shape == (1000, 1000)
- assert res[1].shape == (100, 100)
- assert torch.all(res[0].to_dense() == layer.node_reps[0].to_dense())
- assert torch.all(res[1].to_dense() == layer.node_reps[1].to_dense())
-
-
- def test_one_hot_input_layer_03():
- if torch.cuda.device_count() == 0:
- pytest.skip('No CUDA devices on this host')
- d = _some_data()
- layer = OneHotInputLayer(d)
- device = torch.device('cuda:0')
- layer = layer.to(device)
- print(list(layer.parameters()))
- # assert layer.device.type == 'cuda:0'
- assert layer.node_reps[0].device == device
- assert layer.node_reps[1].device == device
-
-
- def test_one_hot_input_layer_04():
- d = _some_data()
- layer = OneHotInputLayer(d)
- s = repr(layer)
- assert s.startswith('Icosagon one-hot input layer')
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