Ejemplo n.º 1
0
    def create_transform(self, shape, split_dim=1):
        mct = base.MultiscaleCompositeTransform(num_transforms=4,
                                                split_dim=split_dim)
        for transform in [
                standard.AffineScalarTransform(scale=2.),
                standard.AffineScalarTransform(scale=4.),
                standard.AffineScalarTransform(scale=0.5),
                standard.AffineScalarTransform(scale=0.25)
        ]:
            shape = mct.add_transform(transform, shape)

        return mct
Ejemplo n.º 2
0
 def test_inverse(self):
     batch_size = 10
     shape = [2, 3, 4]
     inputs = torch.randn(batch_size, *shape)
     transform = base.InverseTransform(
         standard.AffineScalarTransform(scale=-2.0))
     reference = standard.AffineScalarTransform(scale=-0.5)
     outputs, logabsdet = transform.inverse(inputs)
     outputs_ref, logabsdet_ref = reference.inverse(inputs)
     self.assert_tensor_is_good(outputs, [batch_size] + shape)
     self.assert_tensor_is_good(logabsdet, [batch_size])
     self.assertEqual(outputs, outputs_ref)
     self.assertEqual(logabsdet, logabsdet_ref)
Ejemplo n.º 3
0
 def test_inverse(self):
     batch_size = 10
     shape = [2, 3, 4]
     inputs = torch.randn(batch_size, *shape)
     transforms = [
         standard.AffineScalarTransform(scale=2.0),
         standard.IdentityTransform(),
         standard.AffineScalarTransform(scale=-0.25),
     ]
     composite = base.CompositeTransform(transforms)
     reference = standard.AffineScalarTransform(scale=-0.5)
     outputs, logabsdet = composite.inverse(inputs)
     outputs_ref, logabsdet_ref = reference.inverse(inputs)
     self.assert_tensor_is_good(outputs, [batch_size] + shape)
     self.assert_tensor_is_good(logabsdet, [batch_size])
     self.assertEqual(outputs, outputs_ref)
     self.assertEqual(logabsdet, logabsdet_ref)
Ejemplo n.º 4
0
 def test_case(scale, shift, true_outputs, true_logabsdet):
     with self.subTest(scale=scale, shift=shift):
         transform = standard.AffineScalarTransform(scale=scale,
                                                    shift=shift)
         outputs, logabsdet = transform.inverse(inputs)
         self.assert_tensor_is_good(outputs, [batch_size] + shape)
         self.assert_tensor_is_good(logabsdet, [batch_size])
         self.assertEqual(outputs, true_outputs)
         self.assertEqual(
             logabsdet,
             torch.full([batch_size], true_logabsdet * np.prod(shape)))
Ejemplo n.º 5
0
 def test_case(scale, shift):
     transform = standard.AffineScalarTransform(scale=scale,
                                                shift=shift)
     self.assert_forward_inverse_are_consistent(transform, inputs)