def _assert_attributions(
self,
model: Module,
layer: Module,
inputs: Tensor,
baselines: Union[Tensor, Callable[..., Tensor]],
neuron_ind: Union[int, Tuple[Union[int, slice], ...]],
n_samples: int = 5,
) -> None:
ngs = NeuronGradientShap(model, layer)
nig = NeuronIntegratedGradients(model, layer)
attrs_gs = ngs.attribute(
inputs, neuron_ind, baselines=baselines, n_samples=n_samples, stdevs=0.09
)
if callable(baselines):
baselines = baselines(inputs)
attrs_ig = []
for baseline in torch.unbind(baselines):
attrs_ig.append(
nig.attribute(inputs, neuron_ind, baselines=baseline.unsqueeze(0))
)
combined_attrs_ig = torch.stack(attrs_ig, dim=0).mean(dim=0)
self.assertTrue(ngs.multiplies_by_inputs)
assertTensorAlmostEqual(self, attrs_gs, combined_attrs_ig, 0.5)
def _ig_input_test_assert(
self,
model: Module,
target_layer: Module,
test_input: TensorOrTupleOfTensorsGeneric,
test_neuron: Union[int, Tuple[Union[int, slice], ...]],
expected_input_ig: Union[List[float], Tuple[List[List[float]], ...]],
additional_input: Any = None,
multiply_by_inputs: bool = True,
) -> None:
for internal_batch_size in [None, 5, 20]:
grad = NeuronIntegratedGradients(
model, target_layer, multiply_by_inputs=multiply_by_inputs)
self.assertEquals(grad.multiplies_by_inputs, multiply_by_inputs)
attributions = grad.attribute(
test_input,
test_neuron,
n_steps=200,
method="gausslegendre",
additional_forward_args=additional_input,
internal_batch_size=internal_batch_size,
)
assertTensorTuplesAlmostEqual(self,
attributions,
expected_input_ig,
delta=0.1)
def _ig_input_test_assert(
self,
model,
target_layer,
test_input,
test_neuron,
expected_input_ig,
additional_input=None,
):
for internal_batch_size in [None, 1, 20]:
grad = NeuronIntegratedGradients(model, target_layer)
attributions = grad.attribute(
test_input,
test_neuron,
n_steps=500,
method="gausslegendre",
additional_forward_args=additional_input,
internal_batch_size=internal_batch_size,
)
if isinstance(expected_input_ig, tuple):
for i in range(len(expected_input_ig)):
for j in range(attributions[i].shape[0]):
assertArraysAlmostEqual(
attributions[i][j].squeeze(0).tolist(),
expected_input_ig[i][j],
delta=0.1,
)
else:
assertArraysAlmostEqual(attributions.squeeze(0).tolist(),
expected_input_ig,
delta=0.1)
def _assert_attributions(self,
model,
layer,
inputs,
baselines,
neuron_ind,
n_samples=5):
ngs = NeuronGradientShap(model, layer)
nig = NeuronIntegratedGradients(model, layer)
attrs_gs = ngs.attribute(inputs,
neuron_ind,
baselines=baselines,
n_samples=n_samples,
stdevs=0.09)
if callable(baselines):
baselines = baselines(inputs)
attrs_ig = []
for baseline in baselines:
attrs_ig.append(
nig.attribute(inputs,
neuron_ind,
baselines=baseline.unsqueeze(0)))
attrs_ig = torch.stack(attrs_ig, axis=0).mean(axis=0)
assertTensorAlmostEqual(self, attrs_gs, attrs_ig, 0.5)
def _ig_matching_test_assert(
self,
model: Module,
output_layer: Module,
test_input: Tensor,
baseline: Union[None, Tensor] = None,
) -> None:
out = model(test_input)
input_attrib = IntegratedGradients(model)
ig_attrib = NeuronIntegratedGradients(model, output_layer)
for i in range(out.shape[1]):
ig_vals = input_attrib.attribute(test_input, target=i, baselines=baseline)
neuron_ig_vals = ig_attrib.attribute(test_input, (i,), baselines=baseline)
assertArraysAlmostEqual(
ig_vals.reshape(-1).tolist(),
neuron_ig_vals.reshape(-1).tolist(),
delta=0.001,
)
self.assertEqual(neuron_ig_vals.shape, test_input.shape)
