How to use xenonpy - 10 common examples
To help you get started, we’ve selected a few xenonpy examples, based on popular ways it is used in public projects.
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yoshida-lab / XenonPy / tests / datatools / test_boxcox.py View on Github 
def test_transform_4x1_ravel_2(data):
bc = BoxCox()
bc.fit(data[0].ravel())
trans = bc.transform((data[0].ravel())[:2])
assert trans.shape == (data[2].ravel())[:2].shape
assert np.all(trans == (data[2].ravel())[:2])
inverse = bc.inverse_transform(trans)
assert inverse.shape == (data[0].ravel())[:2].shape
assert np.allclose(inverse, (data[0].ravel())[:2])def test_trainer_fit_1(data):
model = deepcopy(data[0])
trainer = Trainer(model=model, optimizer=Adam(), loss_func=MSELoss())
trainer.fit(*data[1])
assert trainer.total_iterations == 200
assert trainer.total_epochs == 200
trainer.fit(*data[1], epochs=20)
assert trainer.total_iterations == 220
assert trainer.total_epochs == 220
trainer.reset()
assert trainer.total_iterations == 0
assert trainer.total_epochs == 0
trainer.fit(*data[1], epochs=20)
assert trainer.total_iterations == 20
assert trainer.total_epochs == 20def test_trainer_prediction_1(data):
model = deepcopy(data[0])
trainer = Trainer(model=model, optimizer=Adam(lr=0.1), loss_func=MSELoss(), epochs=200)
trainer.extend(TensorConverter())
trainer.fit(*data[1], *data[1])
trainer = Trainer(model=model).extend(TensorConverter())
y_p = trainer.predict(data[1][0])
assert np.any(np.not_equal(y_p, data[1][1].numpy()))
assert np.allclose(y_p, data[1][1].numpy(), rtol=0, atol=0.2)
y_p, y_t = trainer.predict(*data[1])
assert np.any(np.not_equal(y_p, y_t))
assert np.allclose(y_p, y_t, rtol=0, atol=0.2)
val_set = DataLoader(TensorDataset(*data[1]), batch_size=50)
y_p, y_t = trainer.predict(dataset=val_set)
assert np.any(np.not_equal(y_p, y_t))
assert np.allclose(y_p, y_t, rtol=0, atol=0.2)def test_trainer_2(data):
trainer = Trainer()
with pytest.raises(RuntimeError, match='no model for training'):
trainer.fit(*data[1])
with pytest.raises(TypeError, match='parameter `m` must be a instance of '):
trainer.model = {}
trainer.model = data[0]
assert isinstance(trainer.model, torch.nn.Module)
with pytest.raises(RuntimeError, match='no loss function for training'):
trainer.fit(*data[1])
trainer.loss_func = MSELoss()
assert trainer.loss_type == 'train_mse_loss'
assert trainer.loss_func.__class__ == MSELoss
with pytest.raises(RuntimeError, match='no optimizer for training'):
trainer.fit(*data[1])def test_trainer_prediction_1(data):
model = deepcopy(data[0])
trainer = Trainer(model=model, optimizer=Adam(lr=0.1), loss_func=MSELoss(), epochs=200)
trainer.extend(TensorConverter())
trainer.fit(*data[1], *data[1])
trainer = Trainer(model=model).extend(TensorConverter())
y_p = trainer.predict(data[1][0])
assert np.any(np.not_equal(y_p, data[1][1].numpy()))
assert np.allclose(y_p, data[1][1].numpy(), rtol=0, atol=0.2)
y_p, y_t = trainer.predict(*data[1])
assert np.any(np.not_equal(y_p, y_t))
assert np.allclose(y_p, y_t, rtol=0, atol=0.2)
val_set = DataLoader(TensorDataset(*data[1]), batch_size=50)
y_p, y_t = trainer.predict(dataset=val_set)
assert np.any(np.not_equal(y_p, y_t))
assert np.allclose(y_p, y_t, rtol=0, atol=0.2)
with pytest.raises(RuntimeError, match='parameters and are mutually exclusive'):
trainer.predict(*data[1], dataset='not none')def test_trainer_prediction_2():
model = _Net(n_feature=2, n_hidden=10, n_output=2)
n_data = np.ones((100, 2))
x0 = np.random.normal(2 * n_data, 1)
y0 = np.zeros(100)
x1 = np.random.normal(-2 * n_data, 1)
y1 = np.ones(100)
x = np.vstack((x0, x1))
y = np.concatenate((y0, y1))
s = np.arange(x.shape[0])
np.random.shuffle(s)
x, y = x[s], y[s]
trainer = Trainer(model=model, optimizer=Adam(lr=0.1), loss_func=CrossEntropyLoss(), epochs=200)
trainer.extend(TensorConverter(x_dtype=torch.float32, y_dtype=torch.long, argmax=True))
trainer.fit(x, y)
y_p, y_t = trainer.predict(x, y)
assert y_p.shape == (200,)
assert np.all(y_p == y_t)
# trainer.reset()
val_set = DataLoader(ArrayDataset(x, y, dtypes=(torch.float, torch.long)), batch_size=20)
trainer.extend(TensorConverter(x_dtype=torch.float32, y_dtype=torch.long, auto_reshape=False))
y_p, y_t = trainer.predict(dataset=val_set)
assert y_p.shape == (200, 2)
y_p = np.argmax(y_p, 1)
assert np.all(y_p == y_t)def test_trainer_fit_2(data):
model = deepcopy(data[0])
trainer = Trainer(model=model, optimizer=Adam(), loss_func=MSELoss(), epochs=20)
trainer.fit(*data[1], *data[1])
assert trainer.total_iterations == 20
assert trainer.total_epochs == 20
assert (trainer.x_val, trainer.y_val) == data[1]
train_set = DataLoader(TensorDataset(*data[1]))
val_set = DataLoader(TensorDataset(*data[1]))
trainer.fit(training_dataset=train_set, validation_dataset=val_set)
assert trainer.total_iterations == 2020
assert trainer.total_epochs == 40
assert isinstance(trainer.validate_dataset, DataLoader)with pytest.raises(TypeError, match='parameter `m` must be a instance of '):
trainer.model = {}
trainer.model = data[0]
assert isinstance(trainer.model, torch.nn.Module)
with pytest.raises(RuntimeError, match='no loss function for training'):
trainer.fit(*data[1])
trainer.loss_func = MSELoss()
assert trainer.loss_type == 'train_mse_loss'
assert trainer.loss_func.__class__ == MSELoss
with pytest.raises(RuntimeError, match='no optimizer for training'):
trainer.fit(*data[1])
trainer.optimizer = Adam()
assert isinstance(trainer.optimizer, torch.optim.Adam)
assert isinstance(trainer._optimizer_state, dict)
assert isinstance(trainer._init_states, dict)
trainer.lr_scheduler = ExponentialLR(gamma=0.99)
assert isinstance(trainer.lr_scheduler, torch.optim.lr_scheduler.ExponentialLR)def test_trainer_fit_3(data):
model = deepcopy(data[0])
trainer = Trainer(model=model, optimizer=Adam(), loss_func=MSELoss(), epochs=5)
trainer.fit(*data[1])
assert len(trainer.checkpoints.keys()) == 0
trainer.reset()
assert trainer.total_iterations == 0
assert trainer.total_epochs == 0
assert len(trainer.get_checkpoint()) == 0
trainer.fit(*data[1], checkpoint=True)
assert len(trainer.get_checkpoint()) == 5
assert isinstance(trainer.get_checkpoint(2), trainer.checkpoint_tuple)
assert isinstance(trainer.get_checkpoint('cp_2'), trainer.checkpoint_tuple)
with pytest.raises(TypeError, match='parameter must be str or int'):
trainer.get_checkpoint([])def test_persist_1(data):
model = deepcopy(data[0])
trainer = Trainer(model=model, optimizer=Adam(lr=0.1), loss_func=MSELoss(), epochs=200)
trainer.extend(TensorConverter(), Persist('model_dir'))
trainer.fit(*data[1], *data[1])
persist = trainer['persist']
checker = persist._checker
assert isinstance(persist, Persist)
assert isinstance(checker.model, torch.nn.Module)
assert isinstance(checker.describe, dict)
assert isinstance(checker.files, list)
assert set(checker.files) == {'model', 'init_state', 'model_structure', 'describe', 'training_info', 'final_state'}
trainer = Trainer.load(checker)
assert isinstance(trainer.training_info, pd.DataFrame)
assert isinstance(trainer.model, torch.nn.Module)
assert isinstance(trainer._training_info, list)
assert trainer.optimizer is None
Popular xenonpy functions
- xenonpy.datatools.Dataset
- xenonpy.datatools.Splitter
- xenonpy.datatools.transform.BoxCox
- xenonpy.descriptor.base.BaseCompositionFeaturizer
- xenonpy.descriptor.base.BaseFeaturizer
- xenonpy.descriptor.ECFP
- xenonpy.inverse.iqspr.NGram
- xenonpy.mdl.base.BaseQuery
- xenonpy.model.nn.wrap.L1.batch_norm
- xenonpy.model.training.Adam
- xenonpy.model.training.base.BaseRunner
- xenonpy.model.training.base.BaseRunner.check_device
- xenonpy.model.training.Checker
- xenonpy.model.training.extension.TensorConverter
- xenonpy.model.training.MSELoss
- xenonpy.model.training.Trainer
- xenonpy.pipeline._combinator.Just
- xenonpy.utils.config
- xenonpy.utils.math.Product
- xenonpy.utils.ParameterGenerator