Source code for pytorch_lightning.core.lightning
# Copyright The PyTorch Lightning team.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""The LightningModule - an nn.Module with many additional features."""
import collections
import inspect
import logging
import numbers
import os
import tempfile
import uuid
from abc import ABC
from contextlib import contextmanager
from pathlib import Path
from typing import Any, Callable, Dict, List, Mapping, Optional, Tuple, Union
import numpy as np
import torch
from torch import ScriptModule, Tensor
from torch.nn import Module
from torch.optim.optimizer import Optimizer
from torchmetrics import Metric
from pytorch_lightning.core.grads import GradInformation
from pytorch_lightning.core.hooks import CheckpointHooks, DataHooks, ModelHooks
from pytorch_lightning.core.memory import ModelSummary
from pytorch_lightning.core.mixins import DeviceDtypeModuleMixin, HyperparametersMixin
from pytorch_lightning.core.optimizer import LightningOptimizer
from pytorch_lightning.core.saving import ModelIO
from pytorch_lightning.trainer.connectors.logger_connector.fx_validator import FxValidator
from pytorch_lightning.utilities import rank_zero_deprecation, rank_zero_warn
from pytorch_lightning.utilities.apply_func import apply_to_collection, convert_to_tensors
from pytorch_lightning.utilities.cloud_io import get_filesystem
from pytorch_lightning.utilities.distributed import distributed_available, sync_ddp
from pytorch_lightning.utilities.exceptions import MisconfigurationException
from pytorch_lightning.utilities.parsing import collect_init_args
from pytorch_lightning.utilities.signature_utils import is_param_in_hook_signature
from pytorch_lightning.utilities.types import _METRIC_COLLECTION, EPOCH_OUTPUT, STEP_OUTPUT
from pytorch_lightning.utilities.warnings import WarningCache
warning_cache = WarningCache()
log = logging.getLogger(__name__)
[docs]class LightningModule(
ABC,
DeviceDtypeModuleMixin,
HyperparametersMixin,
GradInformation,
ModelIO,
ModelHooks,
DataHooks,
CheckpointHooks,
Module,
):
# Below is for property support of JIT in PyTorch 1.7
# since none of these are important when using JIT, we are going to ignore them.
__jit_unused_properties__ = (
[
"datamodule",
"example_input_array",
"on_gpu",
"current_epoch",
"global_step",
"global_rank",
"local_rank",
"logger",
"model_size",
"automatic_optimization",
"truncated_bptt_steps",
"loaded_optimizer_states_dict",
]
+ DeviceDtypeModuleMixin.__jit_unused_properties__
+ HyperparametersMixin.__jit_unused_properties__
)
def __init__(self, *args: Any, **kwargs: Any) -> None:
super().__init__(*args, **kwargs)
# see (https://github.com/pytorch/pytorch/blob/3e6bb5233f9ca2c5aa55d9cda22a7ee85439aa6e/
# torch/nn/modules/module.py#L227)
torch._C._log_api_usage_once(f"lightning.module.{self.__class__.__name__}")
# pointer to the trainer object
self.trainer = None
self._distrib_type = None
self._device_type = None
# true if using amp
self.use_amp: bool = False
# the precision used
self.precision: int = 32
# optionally can be set by user
self._example_input_array = None
self._datamodule = None
self._current_fx_name: Optional[str] = None
self._current_dataloader_idx: Optional[int] = None
self._automatic_optimization: bool = True
self._truncated_bptt_steps: int = 0
self._param_requires_grad_state = {}
self._metric_attributes: Optional[Dict[int, str]] = None
self._should_prevent_trainer_and_dataloaders_deepcopy: bool = False
# deprecated, will be removed in 1.6
self._loaded_optimizer_states_dict = {}
[docs] def optimizers(
self, use_pl_optimizer: bool = True
) -> Union[Optimizer, LightningOptimizer, List[Optimizer], List[LightningOptimizer]]:
"""
Returns the optimizer(s) that are being used during training. Useful for manual optimization.
Args:
use_pl_optimizer: If ``True``, will wrap the optimizer(s) in a
:class:`~pytorch_lightning.core.optimizer.LightningOptimizer` for automatic handling of precision and
profiling.
Returns:
A single optimizer, or a list of optimizers in case multiple ones are present.
"""
if use_pl_optimizer:
opts = list(self.trainer.lightning_optimizers.values())
else:
opts = self.trainer.optimizers
# single optimizer
if isinstance(opts, list) and len(opts) == 1 and isinstance(opts[0], (Optimizer, LightningOptimizer)):
return opts[0]
# multiple opts
return opts
[docs] def lr_schedulers(self) -> Optional[Union[Any, List[Any]]]:
"""
Returns the learning rate scheduler(s) that are being used during training. Useful for manual optimization.
Returns:
A single scheduler, or a list of schedulers in case multiple ones are present, or ``None`` if no
schedulers were returned in :meth:`configure_optimizers`.
"""
if not self.trainer.lr_schedulers:
return None
# ignore other keys "interval", "frequency", etc.
lr_schedulers = [s["scheduler"] for s in self.trainer.lr_schedulers]
# single scheduler
if len(lr_schedulers) == 1:
return lr_schedulers[0]
# multiple schedulers
return lr_schedulers
@property
def example_input_array(self) -> Any:
"""
The example input array is a specification of what the module can consume in the :meth:`forward` method.
The return type is interpreted as follows:
- Single tensor: It is assumed the model takes a single argument, i.e.,
``model.forward(model.example_input_array)``
- Tuple: The input array should be interpreted as a sequence of positional arguments, i.e.,
``model.forward(*model.example_input_array)``
- Dict: The input array represents named keyword arguments, i.e.,
``model.forward(**model.example_input_array)``
"""
return self._example_input_array
@example_input_array.setter
def example_input_array(self, example: Any) -> None:
self._example_input_array = example
@property
def current_epoch(self) -> int:
"""The current epoch in the Trainer. If no Trainer is attached, this propery is 0."""
return self.trainer.current_epoch if self.trainer else 0
@property
def global_step(self) -> int:
"""Total training batches seen across all epochs. If no Trainer is attached, this propery is 0."""
return self.trainer.global_step if self.trainer else 0
@property
def global_rank(self) -> int:
"""The index of the current process across all nodes and devices."""
return self.trainer.global_rank if self.trainer else 0
@property
def local_rank(self) -> int:
"""The index of the current process within a single node."""
return self.trainer.local_rank if self.trainer else 0
@property
def datamodule(self) -> Any:
warning_cache.deprecation(
"The `LightningModule.datamodule` property is deprecated in v1.3 and will be removed in v1.5."
" Access the datamodule through using `self.trainer.datamodule` instead.",
stacklevel=6,
)
return self._datamodule
@property
def loaded_optimizer_states_dict(self) -> dict:
warning_cache.deprecation(
"The `LightningModule.loaded_optimizer_states_dict` property is deprecated in v1.4"
" and will be removed in v1.6.",
stacklevel=6,
)
return self._loaded_optimizer_states_dict
@loaded_optimizer_states_dict.setter
def loaded_optimizer_states_dict(self, val: dict) -> None:
warning_cache.deprecation(
"The `LightningModule.loaded_optimizer_states_dict` property is deprecated in v1.4"
" and will be removed in v1.6.",
stacklevel=6,
)
self._loaded_optimizer_states_dict = val
@datamodule.setter
def datamodule(self, datamodule: Any) -> None:
self._datamodule = datamodule
@property
def on_gpu(self):
"""
Returns ``True`` if this model is currently located on a GPU.
Useful to set flags around the LightningModule for different CPU vs GPU behavior.
"""
return self.device.type == "cuda"
@property
def automatic_optimization(self) -> bool:
"""
If set to ``False`` you are responsible for calling ``.backward()``, ``.step()``, ``.zero_grad()``.
"""
return self._automatic_optimization
@automatic_optimization.setter
def automatic_optimization(self, automatic_optimization: bool) -> None:
self._automatic_optimization = automatic_optimization
@property
def truncated_bptt_steps(self) -> int:
"""
Enables `Truncated Backpropagation Through Time` in the Trainer when set to a positive integer. It represents
the number of times :meth:`training_step` gets called before backpropagation. If this is > 0, the
:meth:`training_step` receives an additional argument ``hiddens`` and is expected to return a hidden state.
"""
return self._truncated_bptt_steps
@truncated_bptt_steps.setter
def truncated_bptt_steps(self, truncated_bptt_steps: int) -> None:
self._truncated_bptt_steps = truncated_bptt_steps
@property
def logger(self):
"""Reference to the logger object in the Trainer."""
return self.trainer.logger if self.trainer else None
def _apply_batch_transfer_handler(
self, batch: Any, device: Optional[torch.device] = None, dataloader_idx: Optional[int] = None
) -> Any:
device = device or self.device
batch = self.on_before_batch_transfer(batch, dataloader_idx)
if is_param_in_hook_signature(self.transfer_batch_to_device, "dataloader_idx"):
batch = self.transfer_batch_to_device(batch, device, dataloader_idx)
else:
warning_cache.deprecation(
"`transfer_batch_to_device` hook signature has changed in v1.4."
" `dataloader_idx` parameter has been added to it. Support for"
" the old signature will be removed in v1.6"
)
batch = self.transfer_batch_to_device(batch, device)
batch = self.on_after_batch_transfer(batch, dataloader_idx)
return batch
[docs] def print(self, *args, **kwargs) -> None:
r"""
Prints only from process 0. Use this in any distributed mode to log only once.
Args:
*args: The thing to print. The same as for Python's built-in print function.
**kwargs: The same as for Python's built-in print function.
Example::
def forward(self, x):
self.print(x, 'in forward')
"""
if self.trainer.is_global_zero:
progress_bar = self.trainer.progress_bar_callback
if progress_bar is not None and progress_bar.is_enabled:
progress_bar.print(*args, **kwargs)
else:
print(*args, **kwargs)
[docs] def log(
self,
name: str,
value: _METRIC_COLLECTION,
prog_bar: bool = False,
logger: bool = True,
on_step: Optional[bool] = None,
on_epoch: Optional[bool] = None,
reduce_fx: Union[str, Callable] = "default", # TODO: change to 'mean' when `sync_dist_op` is removed in 1.6
tbptt_reduce_fx: Optional = None, # noqa: Remove in 1.6
tbptt_pad_token: Optional = None, # noqa: Remove in 1.6
enable_graph: bool = False,
sync_dist: bool = False,
sync_dist_op: Optional = None, # noqa: Remove in 1.6
sync_dist_group: Optional[Any] = None,
add_dataloader_idx: bool = True,
batch_size: Optional[int] = None,
metric_attribute: Optional[str] = None,
rank_zero_only: Optional[bool] = None,
) -> None:
"""
Log a key, value pair.
Example::
self.log('train_loss', loss)
The default behavior per hook is as follows:
.. csv-table:: ``*`` also applies to the test loop
:header: "LightningModule Hook", "on_step", "on_epoch", "prog_bar", "logger"
:widths: 20, 10, 10, 10, 10
"training_step", "T", "F", "F", "T"
"training_step_end", "T", "F", "F", "T"
"training_epoch_end", "F", "T", "F", "T"
"validation_step*", "F", "T", "F", "T"
"validation_step_end*", "F", "T", "F", "T"
"validation_epoch_end*", "F", "T", "F", "T"
Args:
name: key to log
value: value to log. Can be a ``float``, ``Tensor``, ``Metric``, or a dictionary of the former.
prog_bar: if True logs to the progress bar
logger: if True logs to the logger
on_step: if True logs at this step. None auto-logs at the training_step but not validation/test_step
on_epoch: if True logs epoch accumulated metrics. None auto-logs at the val/test step but not training_step
reduce_fx: reduction function over step values for end of epoch. :meth:`torch.mean` by default.
enable_graph: if True, will not auto detach the graph
sync_dist: if True, reduces the metric across GPUs/TPUs
sync_dist_group: the ddp group to sync across
add_dataloader_idx: if True, appends the index of the current dataloader to
the name (when using multiple). If False, user needs to give unique names for
each dataloader to not mix values
batch_size: Current batch_size. This will be directly inferred from the loaded batch,
but some data structures might need to explicitly provide it.
metric_attribute: To restore the metric state, Lightning requires the reference of the
:class:`torchmetrics.Metric` in your model. This is found automatically if it is a model attribute.
rank_zero_only: Whether the value will be logged only on rank 0. This will prevent synchronization which
would produce a deadlock as not all processes would perform this log call.
"""
if tbptt_reduce_fx is not None:
rank_zero_deprecation(
"`self.log(tbptt_reduce_fx=...)` is no longer supported. The flag will be removed in v1.6."
" Please, open a discussion explaining your use-case in"
" `https://github.com/PyTorchLightning/pytorch-lightning/discussions`"
)
if tbptt_pad_token is not None:
rank_zero_deprecation(
"`self.log(tbptt_pad_token=...)` is no longer supported. The flag will be removed in v1.6."
" Please, open a discussion explaining your use-case in"
" `https://github.com/PyTorchLightning/pytorch-lightning/discussions`"
)
if sync_dist_op is not None:
rank_zero_deprecation(
f"`self.log(sync_dist_op='{sync_dist_op}')` is deprecated and will be removed in v.1.6."
f" Use `self.log(reduce_fx={sync_dist_op})` instead."
)
if reduce_fx == "default":
reduce_fx = sync_dist_op
elif reduce_fx == "default":
reduce_fx = "mean"
# check for invalid values
apply_to_collection(value, dict, self.__check_not_nested, name)
apply_to_collection(
value, object, self.__check_allowed, name, value, wrong_dtype=(numbers.Number, Metric, Tensor, dict)
)
# set the default depending on the fx_name
on_step = self.__auto_choose_log_on_step(on_step)
on_epoch = self.__auto_choose_log_on_epoch(on_epoch)
results = self.trainer._results
assert results is not None
assert self._current_fx_name is not None
FxValidator.check_logging(self._current_fx_name, on_step=on_step, on_epoch=on_epoch)
# make sure user doesn't introduce logic for multi-dataloaders
if "/dataloader_idx_" in name:
raise MisconfigurationException(
f"You called `self.log` with the key `{name}`"
" but it should not contain information about `dataloader_idx`"
)
value = apply_to_collection(value, numbers.Number, self.__to_tensor)
if self.trainer.logger_connector.should_reset_tensors(self._current_fx_name):
# if we started a new epoch (running it's first batch) the hook name has changed
# reset any tensors for the new hook name
results.reset(metrics=False, fx=self._current_fx_name)
if metric_attribute is None and isinstance(value, Metric):
if self._metric_attributes is None:
# compute once
self._metric_attributes = {
id(module): name for name, module in self.named_modules() if isinstance(module, Metric)
}
if not self._metric_attributes:
raise MisconfigurationException(
"Could not find the `LightningModule` attribute for the `torchmetrics.Metric` logged."
" You can fix this by setting an attribute for the metric in your `LightningModule`."
)
# try to find the passed metric in the LightningModule
metric_attribute = self._metric_attributes.get(id(value), None)
if metric_attribute is None:
raise MisconfigurationException(
"Could not find the `LightningModule` attribute for the `torchmetrics.Metric` logged."
f" You can fix this by calling `self.log({name}, ..., metric_attribute=name)` where `name` is one"
f" of {list(self._metric_attributes.values())}"
)
results.log(
self._current_fx_name,
name,
value,
prog_bar=prog_bar,
logger=logger,
on_step=on_step,
on_epoch=on_epoch,
reduce_fx=reduce_fx,
enable_graph=enable_graph,
dataloader_idx=(self._current_dataloader_idx if add_dataloader_idx else None),
batch_size=batch_size,
sync_dist=sync_dist and distributed_available(),
sync_dist_fn=self.trainer.training_type_plugin.reduce or sync_ddp,
sync_dist_group=sync_dist_group,
metric_attribute=metric_attribute,
rank_zero_only=rank_zero_only,
)
self.trainer.logger_connector._current_fx = self._current_fx_name
[docs] def log_dict(
self,
dictionary: Mapping[str, _METRIC_COLLECTION],
prog_bar: bool = False,
logger: bool = True,
on_step: Optional[bool] = None,
on_epoch: Optional[bool] = None,
reduce_fx: Union[str, Callable] = "default", # TODO: change to 'mean' when `sync_dist_op` is removed in 1.6
tbptt_reduce_fx: Optional[Any] = None, # noqa: Remove in 1.6
tbptt_pad_token: Optional[Any] = None, # noqa: Remove in 1.6
enable_graph: bool = False,
sync_dist: bool = False,
sync_dist_op: Optional[Any] = None, # noqa: Remove in 1.6
sync_dist_group: Optional[Any] = None,
add_dataloader_idx: bool = True,
) -> None:
"""
Log a dictionary of values at once.
Example::
values = {'loss': loss, 'acc': acc, ..., 'metric_n': metric_n}
self.log_dict(values)
Args:
dictionary: key value pairs.
The values can be a ``float``, ``Tensor``, ``Metric``, or a dictionary of the former.
prog_bar: if True logs to the progress base
logger: if True logs to the logger
on_step: if True logs at this step. None auto-logs for training_step but not validation/test_step
on_epoch: if True logs epoch accumulated metrics. None auto-logs for val/test step but not training_step
reduce_fx: reduction function over step values for end of epoch. :meth:`torch.mean` by default.
enable_graph: if True, will not auto detach the graph
sync_dist: if True, reduces the metric across GPUs/TPUs
sync_dist_group: the ddp group sync across
add_dataloader_idx: if True, appends the index of the current dataloader to
the name (when using multiple). If False, user needs to give unique names for
each dataloader to not mix values
"""
for k, v in dictionary.items():
self.log(
name=k,
value=v,
prog_bar=prog_bar,
logger=logger,
on_step=on_step,
on_epoch=on_epoch,
reduce_fx=reduce_fx,
enable_graph=enable_graph,
sync_dist=sync_dist,
sync_dist_group=sync_dist_group,
sync_dist_op=sync_dist_op,
tbptt_pad_token=tbptt_pad_token,
tbptt_reduce_fx=tbptt_reduce_fx,
add_dataloader_idx=add_dataloader_idx,
)
@staticmethod
def __check_not_nested(value: dict, name: str) -> dict:
# self-imposed restriction. for simplicity
if any(isinstance(v, dict) for v in value.values()):
raise ValueError(f"`self.log({name}, {value})` was called, but nested dictionaries cannot be logged")
return value
@staticmethod
def __check_allowed(v: Any, name: str, value: Any) -> None:
raise ValueError(f"`self.log({name}, {value})` was called, but `{type(v).__name__}` values cannot be logged")
def __to_tensor(self, value: numbers.Number) -> torch.Tensor:
return torch.tensor(value, device=self.device)
[docs] def log_grad_norm(self, grad_norm_dict: Dict[str, torch.Tensor]) -> None:
"""Override this method to change the default behaviour of ``log_grad_norm``.
Args:
grad_norm_dict: Dictionary containing current grad norm metrics
Example::
# DEFAULT
def log_grad_norm(self, grad_norm_dict):
self.log_dict(grad_norm_dict, on_step=False, on_epoch=True, prog_bar=False, logger=True)
"""
self.log_dict(grad_norm_dict, on_step=True, on_epoch=True, prog_bar=True, logger=True)
[docs] def write_prediction(
self, name: str, value: Union[torch.Tensor, List[torch.Tensor]], filename: str = "predictions.pt"
):
"""
Write predictions to disk using ``torch.save``
Example::
self.write_prediction('pred', torch.tensor(...), filename='my_predictions.pt')
Args:
name: a string indicating the name to save the predictions under
value: the predictions, either a single :class:`~torch.Tensor` or a list of them
filename: name of the file to save the predictions to
Note:
when running in distributed mode, calling ``write_prediction`` will create a file for
each device with respective names: ``filename_rank_0.pt``, ``filename_rank_1.pt``, ...
.. deprecated::v1.3
Will be removed in v1.5.0.
"""
rank_zero_deprecation(
"LightningModule method `write_prediction` was deprecated in v1.3 and will be removed in v1.5."
)
self.trainer._evaluation_loop.predictions._add_prediction(name, value, filename)
[docs] def write_prediction_dict(self, predictions_dict: Dict[str, Any], filename: str = "predictions.pt"):
"""
Write a dictonary of predictions to disk at once using ``torch.save``
Example::
pred_dict = {'pred1': torch.tensor(...), 'pred2': torch.tensor(...)}
self.write_prediction_dict(pred_dict)
Args:
predictions_dict: dict containing predictions, where each prediction should
either be single :class:`~torch.Tensor` or a list of them
Note:
when running in distributed mode, calling ``write_prediction_dict`` will create a file for
each device with respective names: ``filename_rank_0.pt``, ``filename_rank_1.pt``, ...
.. deprecated::v1.3
Will be removed in v1.5.0.
"""
rank_zero_deprecation(
"LightningModule method `write_prediction_dict` was deprecated in v1.3 and will be removed in v1.5."
)
for k, v in predictions_dict.items():
self.write_prediction(k, v, filename)
def __auto_choose_log_on_step(self, on_step: Optional[bool]) -> bool:
if on_step is None:
on_step = False
on_step |= self._current_fx_name in ("training_step", "training_step_end")
return on_step
def __auto_choose_log_on_epoch(self, on_epoch: Optional[bool]) -> bool:
if on_epoch is None:
on_epoch = True
on_epoch &= self._current_fx_name not in ("training_step", "training_step_end")
return on_epoch
[docs] def all_gather(
self, data: Union[torch.Tensor, Dict, List, Tuple], group: Optional[Any] = None, sync_grads: bool = False
):
r"""
Allows users to call ``self.all_gather()`` from the LightningModule, thus making the ``all_gather`` operation
accelerator agnostic. ``all_gather`` is a function provided by accelerators to gather a tensor from several
distributed processes.
Args:
data: int, float, tensor of shape (batch, ...), or a (possibly nested) collection thereof.
group: the process group to gather results from. Defaults to all processes (world)
sync_grads: flag that allows users to synchronize gradients for the all_gather operation
Return:
A tensor of shape (world_size, batch, ...), or if the input was a collection
the output will also be a collection with tensors of this shape.
"""
group = group if group is not None else torch.distributed.group.WORLD
all_gather = self.trainer.accelerator.all_gather
data = convert_to_tensors(data, device=self.device)
return apply_to_collection(data, torch.Tensor, all_gather, group=group, sync_grads=sync_grads)
[docs] def forward(self, *args, **kwargs) -> Any:
r"""
Same as :meth:`torch.nn.Module.forward()`.
Args:
*args: Whatever you decide to pass into the forward method.
**kwargs: Keyword arguments are also possible.
Return:
Your model's output
"""
return super().forward(*args, **kwargs)
[docs] def training_step(self, *args, **kwargs) -> STEP_OUTPUT:
r"""
Here you compute and return the training loss and some additional metrics for e.g.
the progress bar or logger.
Args:
batch (:class:`~torch.Tensor` | (:class:`~torch.Tensor`, ...) | [:class:`~torch.Tensor`, ...]):
The output of your :class:`~torch.utils.data.DataLoader`. A tensor, tuple or list.
batch_idx (int): Integer displaying index of this batch
optimizer_idx (int): When using multiple optimizers, this argument will also be present.
hiddens(:class:`~torch.Tensor`): Passed in if
:paramref:`~pytorch_lightning.core.lightning.LightningModule.truncated_bptt_steps` > 0.
Return:
Any of.
- :class:`~torch.Tensor` - The loss tensor
- ``dict`` - A dictionary. Can include any keys, but must include the key ``'loss'``
- ``None`` - Training will skip to the next batch. This is only for automatic optimization.
This is not supported for multi-GPU or TPU, or using ``DeepSpeed``.
In this step you'd normally do the forward pass and calculate the loss for a batch.
You can also do fancier things like multiple forward passes or something model specific.
Example::
def training_step(self, batch, batch_idx):
x, y, z = batch
out = self.encoder(x)
loss = self.loss(out, x)
return loss
If you define multiple optimizers, this step will be called with an additional
``optimizer_idx`` parameter.
.. code-block:: python
# Multiple optimizers (e.g.: GANs)
def training_step(self, batch, batch_idx, optimizer_idx):
if optimizer_idx == 0:
# do training_step with encoder
...
if optimizer_idx == 1:
# do training_step with decoder
...
If you add truncated back propagation through time you will also get an additional
argument with the hidden states of the previous step.
.. code-block:: python
# Truncated back-propagation through time
def training_step(self, batch, batch_idx, hiddens):
# hiddens are the hidden states from the previous truncated backprop step
...
out, hiddens = self.lstm(data, hiddens)
...
return {"loss": loss, "hiddens": hiddens}
Note:
The loss value shown in the progress bar is smoothed (averaged) over the last values,
so it differs from the actual loss returned in train/validation step.
"""
rank_zero_warn("`training_step` must be implemented to be used with the Lightning Trainer")
[docs] def training_step_end(self, *args, **kwargs) -> STEP_OUTPUT:
"""
Use this when training with dp or ddp2 because :meth:`training_step`
will operate on only part of the batch. However, this is still optional
and only needed for things like softmax or NCE loss.
Note:
If you later switch to ddp or some other mode, this will still be called
so that you don't have to change your code
.. code-block:: python
# pseudocode
sub_batches = split_batches_for_dp(batch)
batch_parts_outputs = [training_step(sub_batch) for sub_batch in sub_batches]
training_step_end(batch_parts_outputs)
Args:
batch_parts_outputs: What you return in `training_step` for each batch part.
Return:
Anything
When using dp/ddp2 distributed backends, only a portion of the batch is inside the training_step:
.. code-block:: python
def training_step(self, batch, batch_idx):
# batch is 1/num_gpus big
x, y = batch
out = self(x)
# softmax uses only a portion of the batch in the denominator
loss = self.softmax(out)
loss = nce_loss(loss)
return loss
If you wish to do something with all the parts of the batch, then use this method to do it:
.. code-block:: python
def training_step(self, batch, batch_idx):
# batch is 1/num_gpus big
x, y = batch
out = self.encoder(x)
return {"pred": out}
def training_step_end(self, training_step_outputs):
gpu_0_pred = training_step_outputs[0]["pred"]
gpu_1_pred = training_step_outputs[1]["pred"]
gpu_n_pred = training_step_outputs[n]["pred"]
# this softmax now uses the full batch
loss = nce_loss([gpu_0_pred, gpu_1_pred, gpu_n_pred])
return loss
See Also:
See the :ref:`advanced/multi_gpu:Multi-GPU training` guide for more details.
"""
[docs] def training_epoch_end(self, outputs: EPOCH_OUTPUT) -> None:
"""
Called at the end of the training epoch with the outputs of all training steps.
Use this in case you need to do something with all the outputs returned by :meth:`training_step`.
.. code-block:: python
# the pseudocode for these calls
train_outs = []
for train_batch in train_data:
out = training_step(train_batch)
train_outs.append(out)
training_epoch_end(train_outs)
Args:
outputs: List of outputs you defined in :meth:`training_step`, or if there are
multiple dataloaders, a list containing a list of outputs for each dataloader.
Return:
None
Note:
If this method is not overridden, this won't be called.
Example::
def training_epoch_end(self, training_step_outputs):
# do something with all training_step outputs
return result
With multiple dataloaders, ``outputs`` will be a list of lists. The outer list contains
one entry per dataloader, while the inner list contains the individual outputs of
each training step for that dataloader.
.. code-block:: python
def training_epoch_end(self, training_step_outputs):
for out in training_step_outputs:
...
"""
[docs] def validation_step(self, *args, **kwargs) -> Optional[STEP_OUTPUT]:
r"""
Operates on a single batch of data from the validation set.
In this step you'd might generate examples or calculate anything of interest like accuracy.
.. code-block:: python
# the pseudocode for these calls
val_outs = []
for val_batch in val_data:
out = validation_step(val_batch)
val_outs.append(out)
validation_epoch_end(val_outs)
Args:
batch (:class:`~torch.Tensor` | (:class:`~torch.Tensor`, ...) | [:class:`~torch.Tensor`, ...]):
The output of your :class:`~torch.utils.data.DataLoader`. A tensor, tuple or list.
batch_idx (int): The index of this batch
dataloader_idx (int): The index of the dataloader that produced this batch
(only if multiple val dataloaders used)
Return:
- Any object or value
- ``None`` - Validation will skip to the next batch
.. code-block:: python
# pseudocode of order
val_outs = []
for val_batch in val_data:
out = validation_step(val_batch)
if defined("validation_step_end"):
out = validation_step_end(out)
val_outs.append(out)
val_outs = validation_epoch_end(val_outs)
.. code-block:: python
# if you have one val dataloader:
def validation_step(self, batch, batch_idx):
...
# if you have multiple val dataloaders:
def validation_step(self, batch, batch_idx, dataloader_idx):
...
Examples::
# CASE 1: A single validation dataset
def validation_step(self, batch, batch_idx):
x, y = batch
# implement your own
out = self(x)
loss = self.loss(out, y)
# log 6 example images
# or generated text... or whatever
sample_imgs = x[:6]
grid = torchvision.utils.make_grid(sample_imgs)
self.logger.experiment.add_image('example_images', grid, 0)
# calculate acc
labels_hat = torch.argmax(out, dim=1)
val_acc = torch.sum(y == labels_hat).item() / (len(y) * 1.0)
# log the outputs!
self.log_dict({'val_loss': loss, 'val_acc': val_acc})
If you pass in multiple val dataloaders, :meth:`validation_step` will have an additional argument.
.. code-block:: python
# CASE 2: multiple validation dataloaders
def validation_step(self, batch, batch_idx, dataloader_idx):
# dataloader_idx tells you which dataset this is.
...
Note:
If you don't need to validate you don't need to implement this method.
Note:
When the :meth:`validation_step` is called, the model has been put in eval mode
and PyTorch gradients have been disabled. At the end of validation,
the model goes back to training mode and gradients are enabled.
"""
[docs] def validation_step_end(self, *args, **kwargs) -> Optional[STEP_OUTPUT]:
"""
Use this when validating with dp or ddp2 because :meth:`validation_step`
will operate on only part of the batch. However, this is still optional
and only needed for things like softmax or NCE loss.
Note:
If you later switch to ddp or some other mode, this will still be called
so that you don't have to change your code.
.. code-block:: python
# pseudocode
sub_batches = split_batches_for_dp(batch)
batch_parts_outputs = [validation_step(sub_batch) for sub_batch in sub_batches]
validation_step_end(batch_parts_outputs)
Args:
batch_parts_outputs: What you return in :meth:`validation_step`
for each batch part.
Return:
None or anything
.. code-block:: python
# WITHOUT validation_step_end
# if used in DP or DDP2, this batch is 1/num_gpus large
def validation_step(self, batch, batch_idx):
# batch is 1/num_gpus big
x, y = batch
out = self.encoder(x)
loss = self.softmax(out)
loss = nce_loss(loss)
self.log("val_loss", loss)
# --------------
# with validation_step_end to do softmax over the full batch
def validation_step(self, batch, batch_idx):
# batch is 1/num_gpus big
x, y = batch
out = self(x)
return out
def validation_step_end(self, val_step_outputs):
for out in val_step_outputs:
...
See Also:
See the :ref:`advanced/multi_gpu:Multi-GPU training` guide for more details.
"""
[docs] def validation_epoch_end(self, outputs: EPOCH_OUTPUT) -> None:
"""
Called at the end of the validation epoch with the outputs of all validation steps.
.. code-block:: python
# the pseudocode for these calls
val_outs = []
for val_batch in val_data:
out = validation_step(val_batch)
val_outs.append(out)
validation_epoch_end(val_outs)
Args:
outputs: List of outputs you defined in :meth:`validation_step`, or if there
are multiple dataloaders, a list containing a list of outputs for each dataloader.
Return:
None
Note:
If you didn't define a :meth:`validation_step`, this won't be called.
Examples:
With a single dataloader:
.. code-block:: python
def validation_epoch_end(self, val_step_outputs):
for out in val_step_outputs:
...
With multiple dataloaders, `outputs` will be a list of lists. The outer list contains
one entry per dataloader, while the inner list contains the individual outputs of
each validation step for that dataloader.
.. code-block:: python
def validation_epoch_end(self, outputs):
for dataloader_output_result in outputs:
dataloader_outs = dataloader_output_result.dataloader_i_outputs
self.log("final_metric", final_value)
"""
[docs] def test_step(self, *args, **kwargs) -> Optional[STEP_OUTPUT]:
r"""
Operates on a single batch of data from the test set.
In this step you'd normally generate examples or calculate anything of interest
such as accuracy.
.. code-block:: python
# the pseudocode for these calls
test_outs = []
for test_batch in test_data:
out = test_step(test_batch)
test_outs.append(out)
test_epoch_end(test_outs)
Args:
batch (:class:`~torch.Tensor` | (:class:`~torch.Tensor`, ...) | [:class:`~torch.Tensor`, ...]):
The output of your :class:`~torch.utils.data.DataLoader`. A tensor, tuple or list.
batch_idx (int): The index of this batch.
dataloader_idx (int): The index of the dataloader that produced this batch
(only if multiple test dataloaders used).
Return:
Any of.
- Any object or value
- ``None`` - Testing will skip to the next batch
.. code-block:: python
# if you have one test dataloader:
def test_step(self, batch, batch_idx):
...
# if you have multiple test dataloaders:
def test_step(self, batch, batch_idx, dataloader_idx):
...
Examples::
# CASE 1: A single test dataset
def test_step(self, batch, batch_idx):
x, y = batch
# implement your own
out = self(x)
loss = self.loss(out, y)
# log 6 example images
# or generated text... or whatever
sample_imgs = x[:6]
grid = torchvision.utils.make_grid(sample_imgs)
self.logger.experiment.add_image('example_images', grid, 0)
# calculate acc
labels_hat = torch.argmax(out, dim=1)
test_acc = torch.sum(y == labels_hat).item() / (len(y) * 1.0)
# log the outputs!
self.log_dict({'test_loss': loss, 'test_acc': test_acc})
If you pass in multiple test dataloaders, :meth:`test_step` will have an additional argument.
.. code-block:: python
# CASE 2: multiple test dataloaders
def test_step(self, batch, batch_idx, dataloader_idx):
# dataloader_idx tells you which dataset this is.
...
Note:
If you don't need to test you don't need to implement this method.
Note:
When the :meth:`test_step` is called, the model has been put in eval mode and
PyTorch gradients have been disabled. At the end of the test epoch, the model goes back
to training mode and gradients are enabled.
"""
[docs] def test_step_end(self, *args, **kwargs) -> Optional[STEP_OUTPUT]:
"""
Use this when testing with dp or ddp2 because :meth:`test_step` will operate
on only part of the batch. However, this is still optional
and only needed for things like softmax or NCE loss.
Note:
If you later switch to ddp or some other mode, this will still be called
so that you don't have to change your code.
.. code-block:: python
# pseudocode
sub_batches = split_batches_for_dp(batch)
batch_parts_outputs = [test_step(sub_batch) for sub_batch in sub_batches]
test_step_end(batch_parts_outputs)
Args:
batch_parts_outputs: What you return in :meth:`test_step` for each batch part.
Return:
None or anything
.. code-block:: python
# WITHOUT test_step_end
# if used in DP or DDP2, this batch is 1/num_gpus large
def test_step(self, batch, batch_idx):
# batch is 1/num_gpus big
x, y = batch
out = self(x)
loss = self.softmax(out)
self.log("test_loss", loss)
# --------------
# with test_step_end to do softmax over the full batch
def test_step(self, batch, batch_idx):
# batch is 1/num_gpus big
x, y = batch
out = self.encoder(x)
return out
def test_step_end(self, output_results):
# this out is now the full size of the batch
all_test_step_outs = output_results.out
loss = nce_loss(all_test_step_outs)
self.log("test_loss", loss)
See Also:
See the :ref:`advanced/multi_gpu:Multi-GPU training` guide for more details.
"""
[docs] def test_epoch_end(self, outputs: EPOCH_OUTPUT) -> None:
"""
Called at the end of a test epoch with the output of all test steps.
.. code-block:: python
# the pseudocode for these calls
test_outs = []
for test_batch in test_data:
out = test_step(test_batch)
test_outs.append(out)
test_epoch_end(test_outs)
Args:
outputs: List of outputs you defined in :meth:`test_step_end`, or if there
are multiple dataloaders, a list containing a list of outputs for each dataloader
Return:
None
Note:
If you didn't define a :meth:`test_step`, this won't be called.
Examples:
With a single dataloader:
.. code-block:: python
def test_epoch_end(self, outputs):
# do something with the outputs of all test batches
all_test_preds = test_step_outputs.predictions
some_result = calc_all_results(all_test_preds)
self.log(some_result)
With multiple dataloaders, `outputs` will be a list of lists. The outer list contains
one entry per dataloader, while the inner list contains the individual outputs of
each test step for that dataloader.
.. code-block:: python
def test_epoch_end(self, outputs):
final_value = 0
for dataloader_outputs in outputs:
for test_step_out in dataloader_outputs:
# do something
final_value += test_step_out
self.log("final_metric", final_value)
"""
[docs] def predict_step(self, batch: Any, batch_idx: int, dataloader_idx: Optional[int] = None) -> Any:
"""
Step function called during :meth:`~pytorch_lightning.trainer.trainer.Trainer.predict`.
By default, it calls :meth:`~pytorch_lightning.core.lightning.LightningModule.forward`.
Override to add any processing logic.
The :meth:`~pytorch_lightning.core.lightning.LightningModule.predict_step` is used
to scale inference on multi-devices.
To prevent an OOM error, it is possible to use :class:`~pytorch_lightning.callbacks.BasePredictionWriter`
callback to write the predictions to disk or database after each batch or on epoch end.
The :class:`~pytorch_lightning.callbacks.BasePredictionWriter` should be used while using a spawn
based accelerator. This happens for ``Trainer(accelerator="ddp_spawn")``
or training on 8 TPU cores with ``Trainer(tpu_cores=8)`` as predictions won't be returned.
Example ::
class MyModel(LightningModule):
def predicts_step(self, batch, batch_idx, dataloader_idx):
return self(batch)
dm = ...
model = MyModel()
trainer = Trainer(gpus=2)
predictions = trainer.predict(model, dm)
Args:
batch: Current batch
batch_idx: Index of current batch
dataloader_idx: Index of the current dataloader
Return:
Predicted output
"""
return self(batch)
[docs] def configure_callbacks(self):
"""
Configure model-specific callbacks.
When the model gets attached, e.g., when ``.fit()`` or ``.test()`` gets called,
the list returned here will be merged with the list of callbacks passed to the Trainer's ``callbacks`` argument.
If a callback returned here has the same type as one or several callbacks already present in
the Trainer's callbacks list, it will take priority and replace them.
In addition, Lightning will make sure :class:`~pytorch_lightning.callbacks.model_checkpoint.ModelCheckpoint`
callbacks run last.
Return:
A list of callbacks which will extend the list of callbacks in the Trainer.
Example::
def configure_callbacks(self):
early_stop = EarlyStopping(monitor"val_acc", mode="max")
checkpoint = ModelCheckpoint(monitor="val_loss")
return [early_stop, checkpoint]
Note:
Certain callback methods like :meth:`~pytorch_lightning.callbacks.base.Callback.on_init_start`
will never be invoked on the new callbacks returned here.
"""
return []
[docs] def configure_optimizers(self):
r"""
Choose what optimizers and learning-rate schedulers to use in your optimization.
Normally you'd need one. But in the case of GANs or similar you might have multiple.
Return:
Any of these 6 options.
- **Single optimizer**.
- **List or Tuple** of optimizers.
- **Two lists** - The first list has multiple optimizers, and the second has multiple LR schedulers
(or multiple ``lr_dict``).
- **Dictionary**, with an ``"optimizer"`` key, and (optionally) a ``"lr_scheduler"``
key whose value is a single LR scheduler or ``lr_dict``.
- **Tuple of dictionaries** as described above, with an optional ``"frequency"`` key.
- **None** - Fit will run without any optimizer.
The ``lr_dict`` is a dictionary which contains the scheduler and its associated configuration.
The default configuration is shown below.
.. code-block:: python
lr_dict = {
# REQUIRED: The scheduler instance
"scheduler": lr_scheduler,
# The unit of the scheduler's step size, could also be 'step'.
# 'epoch' updates the scheduler on epoch end whereas 'step'
# updates it after a optimizer update.
"interval": "epoch",
# How many epochs/steps should pass between calls to
# `scheduler.step()`. 1 corresponds to updating the learning
# rate after every epoch/step.
"frequency": 1,
# Metric to to monitor for schedulers like `ReduceLROnPlateau`
"monitor": "val_loss",
# If set to `True`, will enforce that the value specified 'monitor'
# is available when the scheduler is updated, thus stopping
# training if not found. If set to `False`, it will only produce a warning
"strict": True,
# If using the `LearningRateMonitor` callback to monitor the
# learning rate progress, this keyword can be used to specify
# a custom logged name
"name": None,
}
When there are schedulers in which the ``.step()`` method is conditioned on a value, such as the
:class:`torch.optim.lr_scheduler.ReduceLROnPlateau` scheduler, Lightning requires that the ``lr_dict``
contains the keyword ``"monitor"`` set to the metric name that the scheduler should be conditioned on.
.. testcode::
# The ReduceLROnPlateau scheduler requires a monitor
def configure_optimizers(self):
optimizer = Adam(...)
return {
"optimizer": optimizer,
"lr_scheduler": {
"scheduler": ReduceLROnPlateau(optimizer, ...),
"monitor": "metric_to_track",
},
}
# In the case of two optimizers, only one using the ReduceLROnPlateau scheduler
def configure_optimizers(self):
optimizer1 = Adam(...)
optimizer2 = SGD(...)
scheduler1 = ReduceLROnPlateau(optimizer1, ...)
scheduler2 = LambdaLR(optimizer2, ...)
return (
{
"optimizer": optimizer1,
"lr_scheduler": {
"scheduler": scheduler1,
"monitor": "metric_to_track",
},
},
{"optimizer": optimizer2, "lr_scheduler": scheduler2},
)
Metrics can be made available to monitor by simply logging it using
``self.log('metric_to_track', metric_val)`` in your :class:`~pytorch_lightning.core.lightning.LightningModule`.
Note:
The ``frequency`` value specified in a dict along with the ``optimizer`` key is an int corresponding
to the number of sequential batches optimized with the specific optimizer.
It should be given to none or to all of the optimizers.
There is a difference between passing multiple optimizers in a list,
and passing multiple optimizers in dictionaries with a frequency of 1:
- In the former case, all optimizers will operate on the given batch in each optimization step.
- In the latter, only one optimizer will operate on the given batch at every step.
This is different from the ``frequency`` value specified in the ``lr_dict`` mentioned above.
.. code-block:: python
def configure_optimizers(self):
optimizer_one = torch.optim.SGD(self.model.parameters(), lr=0.01)
optimizer_two = torch.optim.SGD(self.model.parameters(), lr=0.01)
return [
{"optimizer": optimizer_one, "frequency": 5},
{"optimizer": optimizer_two, "frequency": 10},
]
In this example, the first optimizer will be used for the first 5 steps,
the second optimizer for the next 10 steps and that cycle will continue.
If an LR scheduler is specified for an optimizer using the ``lr_scheduler`` key in the above dict,
the scheduler will only be updated when its optimizer is being used.
Examples::
# most cases. no learning rate scheduler
def configure_optimizers(self):
return Adam(self.parameters(), lr=1e-3)
# multiple optimizer case (e.g.: GAN)
def configure_optimizers(self):
gen_opt = Adam(self.model_gen.parameters(), lr=0.01)
dis_opt = Adam(self.model_dis.parameters(), lr=0.02)
return gen_opt, dis_opt
# example with learning rate schedulers
def configure_optimizers(self):
gen_opt = Adam(self.model_gen.parameters(), lr=0.01)
dis_opt = Adam(self.model_dis.parameters(), lr=0.02)
dis_sch = CosineAnnealing(dis_opt, T_max=10)
return [gen_opt, dis_opt], [dis_sch]
# example with step-based learning rate schedulers
# each optimizer has its own scheduler
def configure_optimizers(self):
gen_opt = Adam(self.model_gen.parameters(), lr=0.01)
dis_opt = Adam(self.model_dis.parameters(), lr=0.02)
gen_sch = {
'scheduler': ExponentialLR(gen_opt, 0.99),
'interval': 'step' # called after each training step
}
dis_sch = CosineAnnealing(dis_opt, T_max=10) # called every epoch
return [gen_opt, dis_opt], [gen_sch, dis_sch]
# example with optimizer frequencies
# see training procedure in `Improved Training of Wasserstein GANs`, Algorithm 1
# https://arxiv.org/abs/1704.00028
def configure_optimizers(self):
gen_opt = Adam(self.model_gen.parameters(), lr=0.01)
dis_opt = Adam(self.model_dis.parameters(), lr=0.02)
n_critic = 5
return (
{'optimizer': dis_opt, 'frequency': n_critic},
{'optimizer': gen_opt, 'frequency': 1}
)
Note:
Some things to know:
- Lightning calls ``.backward()`` and ``.step()`` on each optimizer and learning rate scheduler as needed.
- If you use 16-bit precision (``precision=16``), Lightning will automatically handle the optimizers.
- If you use multiple optimizers, :meth:`training_step` will have an additional ``optimizer_idx`` parameter.
- If you use :class:`torch.optim.LBFGS`, Lightning handles the closure function automatically for you.
- If you use multiple optimizers, gradients will be calculated only for the parameters of current optimizer
at each training step.
- If you need to control how often those optimizers step or override the default ``.step()`` schedule,
override the :meth:`optimizer_step` hook.
"""
rank_zero_warn("`configure_optimizers` must be implemented to be used with the Lightning Trainer")
[docs] def manual_backward(self, loss: Tensor, *args, **kwargs) -> None:
"""
Call this directly from your :meth:`training_step` when doing optimizations manually.
By using this, Lightning can ensure that all the proper scaling gets applied when using mixed precision.
See :ref:`manual optimization<common/optimizers:Manual optimization>` for more examples.
Example::
def training_step(...):
opt = self.optimizers()
loss = ...
opt.zero_grad()
# automatically applies scaling, etc...
self.manual_backward(loss)
opt.step()
Args:
loss: The tensor on which to compute gradients. Must have a graph attached.
*args: Additional positional arguments to be forwarded to :meth:`~torch.Tensor.backward`
**kwargs: Additional keyword arguments to be forwarded to :meth:`~torch.Tensor.backward`
"""
# make sure we're using manual opt
self._verify_is_manual_optimization("manual_backward")
# backward
self.trainer.fit_loop.epoch_loop.batch_loop.backward(loss, None, None, *args, **kwargs)
[docs] def backward(
self, loss: Tensor, optimizer: Optional[Optimizer], optimizer_idx: Optional[int], *args, **kwargs
) -> None:
"""
Called to perform backward on the loss returned in :meth:`training_step`.
Override this hook with your own implementation if you need to.
Args:
loss: The loss tensor returned by :meth:`training_step`. If gradient accumulation is used, the loss here
holds the normalized value (scaled by 1 / accumulation steps).
optimizer: Current optimizer being used. ``None`` if using manual optimization.
optimizer_idx: Index of the current optimizer being used. ``None`` if using manual optimization.
Example::
def backward(self, loss, optimizer, optimizer_idx):
loss.backward()
"""
loss.backward(*args, **kwargs)
[docs] def toggle_optimizer(self, optimizer: Optimizer, optimizer_idx: int):
"""
Makes sure only the gradients of the current optimizer's parameters are calculated
in the training step to prevent dangling gradients in multiple-optimizer setup.
It works with :meth:`untoggle_optimizer` to make sure ``param_requires_grad_state`` is properly reset.
Override for your own behavior.
Args:
optimizer: Current optimizer used in the training loop
optimizer_idx: Current optimizer idx in the training loop
Note:
Only called when using multiple optimizers
"""
# Iterate over all optimizer parameters to preserve their `requires_grad` information
# in case these are pre-defined during `configure_optimizers`
param_requires_grad_state = {}
for opt in self.optimizers(use_pl_optimizer=False):
for group in opt.param_groups:
for param in group["params"]:
# If a param already appear in param_requires_grad_state, continue
if param in param_requires_grad_state:
continue
param_requires_grad_state[param] = param.requires_grad
param.requires_grad = False
# Then iterate over the current optimizer's parameters and set its `requires_grad`
# properties accordingly
for group in optimizer.param_groups:
for param in group["params"]:
param.requires_grad = param_requires_grad_state[param]
self._param_requires_grad_state = param_requires_grad_state
[docs] def untoggle_optimizer(self, optimizer_idx: int):
"""
Resets the state of required gradients that were toggled with :meth:`toggle_optimizer`.
Override for your own behavior.
Args:
optimizer_idx: Current optimizer idx in the training loop
Note:
Only called when using multiple optimizers
"""
for opt_idx, opt in enumerate(self.optimizers(use_pl_optimizer=False)):
if optimizer_idx != opt_idx:
for group in opt.param_groups:
for param in group["params"]:
if param in self._param_requires_grad_state:
param.requires_grad = self._param_requires_grad_state[param]
# save memory
self._param_requires_grad_state = {}
[docs] def optimizer_step(
self,
epoch: int = None,
batch_idx: int = None,
optimizer: Optimizer = None,
optimizer_idx: int = None,
optimizer_closure: Optional[Callable] = None,
on_tpu: bool = None,
using_native_amp: bool = None,
using_lbfgs: bool = None,
) -> None:
r"""
Override this method to adjust the default way the
:class:`~pytorch_lightning.trainer.trainer.Trainer` calls each optimizer.
By default, Lightning calls ``step()`` and ``zero_grad()`` as shown in the example
once per optimizer. This method (and ``zero_grad()``) won't be called during the
accumulation phase when ``Trainer(accumulate_grad_batches != 1)``.
Warning:
If you are overriding this method, make sure that you pass the ``optimizer_closure`` parameter
to ``optimizer.step()`` function as shown in the examples. This ensures that
``training_step()``, ``optimizer.zero_grad()``, ``backward()`` are called within the training loop.
Args:
epoch: Current epoch
batch_idx: Index of current batch
optimizer: A PyTorch optimizer
optimizer_idx: If you used multiple optimizers, this indexes into that list.
optimizer_closure: Closure for all optimizers
on_tpu: ``True`` if TPU backward is required
using_native_amp: ``True`` if using native amp
using_lbfgs: True if the matching optimizer is :class:`torch.optim.LBFGS`
Examples::
# DEFAULT
def optimizer_step(self, epoch, batch_idx, optimizer, optimizer_idx,
optimizer_closure, on_tpu, using_native_amp, using_lbfgs):
optimizer.step(closure=optimizer_closure)
# Alternating schedule for optimizer steps (i.e.: GANs)
def optimizer_step(self, epoch, batch_idx, optimizer, optimizer_idx,
optimizer_closure, on_tpu, using_native_amp, using_lbfgs):
# update generator opt every step
if optimizer_idx == 0:
optimizer.step(closure=optimizer_closure)
# update discriminator opt every 2 steps
if optimizer_idx == 1:
if (batch_idx + 1) % 2 == 0 :
optimizer.step(closure=optimizer_closure)
# ...
# add as many optimizers as you want
Here's another example showing how to use this for more advanced things such as
learning rate warm-up:
.. code-block:: python
# learning rate warm-up
def optimizer_step(
self,
epoch,
batch_idx,
optimizer,
optimizer_idx,
optimizer_closure,
on_tpu,
using_native_amp,
using_lbfgs,
):
# warm up lr
if self.trainer.global_step < 500:
lr_scale = min(1.0, float(self.trainer.global_step + 1) / 500.0)
for pg in optimizer.param_groups:
pg["lr"] = lr_scale * self.learning_rate
# update params
optimizer.step(closure=optimizer_closure)
"""
optimizer.step(closure=optimizer_closure)
[docs] def optimizer_zero_grad(self, epoch: int, batch_idx: int, optimizer: Optimizer, optimizer_idx: int):
"""Override this method to change the default behaviour of ``optimizer.zero_grad()``.
Args:
epoch: Current epoch
batch_idx: Index of current batch
optimizer: A PyTorch optimizer
optimizer_idx: If you used multiple optimizers this indexes into that list.
Examples::
# DEFAULT
def optimizer_zero_grad(self, epoch, batch_idx, optimizer, optimizer_idx):
optimizer.zero_grad()
# Set gradients to `None` instead of zero to improve performance.
def optimizer_zero_grad(self, epoch, batch_idx, optimizer, optimizer_idx):
optimizer.zero_grad(set_to_none=True)
See :meth:`torch.optim.Optimizer.zero_grad` for the explanation of the above example.
"""
optimizer.zero_grad()
[docs] def tbptt_split_batch(self, batch: Tensor, split_size: int) -> list:
r"""
When using truncated backpropagation through time, each batch must be split along the
time dimension. Lightning handles this by default, but for custom behavior override
this function.
Args:
batch: Current batch
split_size: The size of the split
Return:
List of batch splits. Each split will be passed to :meth:`training_step` to enable truncated
back propagation through time. The default implementation splits root level Tensors and
Sequences at dim=1 (i.e. time dim). It assumes that each time dim is the same length.
Examples::
def tbptt_split_batch(self, batch, split_size):
splits = []
for t in range(0, time_dims[0], split_size):
batch_split = []
for i, x in enumerate(batch):
if isinstance(x, torch.Tensor):
split_x = x[:, t:t + split_size]
elif isinstance(x, collections.Sequence):
split_x = [None] * len(x)
for batch_idx in range(len(x)):
split_x[batch_idx] = x[batch_idx][t:t + split_size]
batch_split.append(split_x)
splits.append(batch_split)
return splits
Note:
Called in the training loop after
:meth:`~pytorch_lightning.callbacks.base.Callback.on_batch_start`
if :paramref:`~pytorch_lightning.core.lightning.LightningModule.truncated_bptt_steps` > 0.
Each returned batch split is passed separately to :meth:`training_step`.
"""
time_dims = [len(x[0]) for x in batch if isinstance(x, (torch.Tensor, collections.Sequence))]
assert len(time_dims) >= 1, "Unable to determine batch time dimension"
assert all(x == time_dims[0] for x in time_dims), "Batch time dimension length is ambiguous"
splits = []
for t in range(0, time_dims[0], split_size):
batch_split = []
for i, x in enumerate(batch):
if isinstance(x, torch.Tensor):
split_x = x[:, t : t + split_size]
elif isinstance(x, collections.Sequence):
split_x = [None] * len(x)
for batch_idx in range(len(x)):
split_x[batch_idx] = x[batch_idx][t : t + split_size]
batch_split.append(split_x)
splits.append(batch_split)
return splits
[docs] def summarize(self, mode: Optional[str] = "top", max_depth: Optional[int] = None) -> Optional[ModelSummary]:
"""
Summarize this LightningModule.
Args:
mode: Can be either ``'top'`` (summarize only direct submodules) or ``'full'`` (summarize all layers).
.. deprecated:: v1.4
This parameter was deprecated in v1.4 in favor of `max_depth` and will be removed in v1.6.
max_depth: The maximum depth of layer nesting that the summary will include. A value of 0 turns the
layer summary off. Default: 1.
Return:
The model summary object
"""
model_summary = None
# temporary mapping from mode to max_depth
if max_depth is None:
if mode in ModelSummary.MODES:
max_depth = ModelSummary.MODES[mode]
rank_zero_deprecation(
f"Argument `mode` in `LightningModule.summarize` is deprecated in v1.4"
f" and will be removed in v1.6. Use `max_depth={max_depth}` to replicate `mode={mode}` behavior."
)
model_summary = ModelSummary(self, max_depth=max_depth)
elif mode is not None:
raise MisconfigurationException(f"`mode` can be None, {', '.join(ModelSummary.MODES)}, got {mode}")
else:
model_summary = ModelSummary(self, max_depth=max_depth)
log.info("\n" + str(model_summary))
return model_summary
[docs] def freeze(self) -> None:
r"""
Freeze all params for inference.
Example::
model = MyLightningModule(...)
model.freeze()
"""
for param in self.parameters():
param.requires_grad = False
self.eval()
[docs] def unfreeze(self) -> None:
"""
Unfreeze all parameters for training.
.. code-block:: python
model = MyLightningModule(...)
model.unfreeze()
"""
for param in self.parameters():
param.requires_grad = True
self.train()
[docs] def get_progress_bar_dict(self) -> Dict[str, Union[int, str]]:
r"""
Implement this to override the default items displayed in the progress bar.
By default it includes the average loss value, split index of BPTT (if used)
and the version of the experiment when using a logger.
.. code-block::
Epoch 1: 4%|▎ | 40/1095 [00:03<01:37, 10.84it/s, loss=4.501, v_num=10]
Here is an example how to override the defaults:
.. code-block:: python
def get_progress_bar_dict(self):
# don't show the version number
items = super().get_progress_bar_dict()
items.pop("v_num", None)
return items
Return:
Dictionary with the items to be displayed in the progress bar.
"""
# call .item() only once but store elements without graphs
running_train_loss = self.trainer.fit_loop.running_loss.mean()
avg_training_loss = None
if running_train_loss is not None:
avg_training_loss = running_train_loss.cpu().item()
elif self.automatic_optimization:
avg_training_loss = float("NaN")
tqdm_dict = {}
if avg_training_loss is not None:
tqdm_dict["loss"] = f"{avg_training_loss:.3g}"
module_tbptt_enabled = self.truncated_bptt_steps > 0
trainer_tbptt_enabled = self.trainer.truncated_bptt_steps is not None and self.trainer.truncated_bptt_steps > 0
if module_tbptt_enabled or trainer_tbptt_enabled:
tqdm_dict["split_idx"] = self.trainer.fit_loop.split_idx
if self.trainer.logger is not None and self.trainer.logger.version is not None:
version = self.trainer.logger.version
# show last 4 places of long version strings
version = version[-4:] if isinstance(version, str) else version
tqdm_dict["v_num"] = version
return tqdm_dict
def _verify_is_manual_optimization(self, fn_name):
if self.automatic_optimization:
raise MisconfigurationException(
f"to use {fn_name}, please disable automatic optimization:"
" set model property `automatic_optimization` as False"
)
@classmethod
def _auto_collect_arguments(cls, frame=None) -> Tuple[Dict, Dict]:
"""
Collect all module arguments in the current constructor and all child constructors.
The child constructors are all the ``__init__`` methods that reach the current class through
(chained) ``super().__init__()`` calls.
Args:
frame: instance frame
Returns:
self_arguments: arguments dictionary of the first instance
parents_arguments: arguments dictionary of the parent's instances
"""
if not frame:
frame = inspect.currentframe()
frame_args = collect_init_args(frame.f_back, [])
self_arguments = frame_args[-1]
# set hyper_parameters in child
self_arguments = self_arguments
parents_arguments = {}
# add all arguments from parents
for args in frame_args[:-1]:
parents_arguments.update(args)
return self_arguments, parents_arguments
@torch.no_grad()
def to_onnx(self, file_path: Union[str, Path], input_sample: Optional[Any] = None, **kwargs):
"""
Saves the model in ONNX format.
Args:
file_path: The path of the file the onnx model should be saved to.
input_sample: An input for tracing. Default: None (Use self.example_input_array)
**kwargs: Will be passed to torch.onnx.export function.
Example:
>>> class SimpleModel(LightningModule):
... def __init__(self):
... super().__init__()
... self.l1 = torch.nn.Linear(in_features=64, out_features=4)
...
... def forward(self, x):
... return torch.relu(self.l1(x.view(x.size(0), -1)))
>>> with tempfile.NamedTemporaryFile(suffix='.onnx', delete=False) as tmpfile:
... model = SimpleModel()
... input_sample = torch.randn((1, 64))
... model.to_onnx(tmpfile.name, input_sample, export_params=True)
... os.path.isfile(tmpfile.name)
True
"""
mode = self.training
if input_sample is None:
if self.example_input_array is None:
raise ValueError(
"Could not export to ONNX since neither `input_sample` nor"
" `model.example_input_array` attribute is set."
)
input_sample = self.example_input_array
input_sample = self._apply_batch_transfer_handler(input_sample)
if "example_outputs" not in kwargs:
self.eval()
if isinstance(input_sample, Tuple):
kwargs["example_outputs"] = self(*input_sample)
else:
kwargs["example_outputs"] = self(input_sample)
torch.onnx.export(self, input_sample, file_path, **kwargs)
self.train(mode)
@torch.no_grad()
def to_torchscript(
self,
file_path: Optional[Union[str, Path]] = None,
method: Optional[str] = "script",
example_inputs: Optional[Any] = None,
**kwargs,
) -> Union[ScriptModule, Dict[str, ScriptModule]]:
"""
By default compiles the whole model to a :class:`~torch.jit.ScriptModule`.
If you want to use tracing, please provided the argument ``method='trace'`` and make sure that either the
`example_inputs` argument is provided, or the model has :attr:`example_input_array` set.
If you would like to customize the modules that are scripted you should override this method.
In case you want to return multiple modules, we recommend using a dictionary.
Args:
file_path: Path where to save the torchscript. Default: None (no file saved).
method: Whether to use TorchScript's script or trace method. Default: 'script'
example_inputs: An input to be used to do tracing when method is set to 'trace'.
Default: None (uses :attr:`example_input_array`)
**kwargs: Additional arguments that will be passed to the :func:`torch.jit.script` or
:func:`torch.jit.trace` function.
Note:
- Requires the implementation of the
:meth:`~pytorch_lightning.core.lightning.LightningModule.forward` method.
- The exported script will be set to evaluation mode.
- It is recommended that you install the latest supported version of PyTorch
to use this feature without limitations. See also the :mod:`torch.jit`
documentation for supported features.
Example:
>>> class SimpleModel(LightningModule):
... def __init__(self):
... super().__init__()
... self.l1 = torch.nn.Linear(in_features=64, out_features=4)
...
... def forward(self, x):
... return torch.relu(self.l1(x.view(x.size(0), -1)))
...
>>> model = SimpleModel()
>>> torch.jit.save(model.to_torchscript(), "model.pt") # doctest: +SKIP
>>> os.path.isfile("model.pt") # doctest: +SKIP
>>> torch.jit.save(model.to_torchscript(file_path="model_trace.pt", method='trace', # doctest: +SKIP
... example_inputs=torch.randn(1, 64))) # doctest: +SKIP
>>> os.path.isfile("model_trace.pt") # doctest: +SKIP
True
Return:
This LightningModule as a torchscript, regardless of whether `file_path` is
defined or not.
"""
mode = self.training
if method == "script":
torchscript_module = torch.jit.script(self.eval(), **kwargs)
elif method == "trace":
# if no example inputs are provided, try to see if model has example_input_array set
if example_inputs is None:
if self.example_input_array is None:
raise ValueError(
"Choosing method=`trace` requires either `example_inputs`"
" or `model.example_input_array` to be defined."
)
example_inputs = self.example_input_array
# automatically send example inputs to the right device and use trace
example_inputs = self._apply_batch_transfer_handler(example_inputs)
torchscript_module = torch.jit.trace(func=self.eval(), example_inputs=example_inputs, **kwargs)
else:
raise ValueError(f"The 'method' parameter only supports 'script' or 'trace', but value given was: {method}")
self.train(mode)
if file_path is not None:
fs = get_filesystem(file_path)
with fs.open(file_path, "wb") as f:
torch.jit.save(torchscript_module, f)
return torchscript_module
@property
def model_size(self) -> float:
"""
The model's size in megabytes. The computation includes everything in the
:meth:`~torch.nn.Module.state_dict`, i.e., by default the parameteters and buffers.
"""
# todo: think about better way without need to dump model to drive
tmp_name = f"{uuid.uuid4().hex}.pt"
torch.save(self.state_dict(), tmp_name)
size_mb = os.path.getsize(tmp_name) / 1e6
os.remove(tmp_name)
return size_mb
[docs] def add_to_queue(self, queue: torch.multiprocessing.SimpleQueue) -> None:
"""
Appends the :attr:`trainer.callback_metrics` dictionary to the given queue.
To avoid issues with memory sharing, we cast the data to numpy.
Args:
queue: the instance of the queue to append the data.
"""
callback_metrics: dict = apply_to_collection(
self.trainer.callback_metrics, torch.Tensor, lambda x: x.cpu().numpy()
) # send as numpy to avoid issues with memory sharing
queue.put(callback_metrics)
[docs] def get_from_queue(self, queue: torch.multiprocessing.SimpleQueue) -> None:
"""
Retrieve the :attr:`trainer.callback_metrics` dictionary from the given queue.
To preserve consistency, we cast back the data to ``torch.Tensor``.
Args:
queue: the instance of the queue from where to get the data.
"""
# NOTE: `add_to_queue` needs to be called before
callback_metrics: dict = queue.get()
self.trainer.callback_metrics.update(
apply_to_collection(callback_metrics, np.ndarray, lambda x: torch.tensor(x))
)
@contextmanager
def _prevent_trainer_and_dataloaders_deepcopy(self) -> None:
self._should_prevent_trainer_and_dataloaders_deepcopy = True
yield
self._should_prevent_trainer_and_dataloaders_deepcopy = False
def __getstate__(self) -> Dict[str, Any]:
state = dict(self.__dict__)
if self._should_prevent_trainer_and_dataloaders_deepcopy:
state["trainer"] = None
state["_datamodule"] = None
state.pop("train_dataloader", None)
state.pop("val_dataloader", None)
state.pop("test_dataloader", None)
state.pop("predict_dataloader", None)
return state
