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torch_rnn_classifier.py
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torch_rnn_classifier.py
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import numpy as np
from operator import itemgetter
import torch
import torch.nn as nn
import torch.utils.data
from torch_model_base import TorchModelBase
import utils
__author__ = "Christopher Potts"
__version__ = "CS224u, Stanford, Spring 2022"
class TorchRNNDataset(torch.utils.data.Dataset):
def __init__(self, sequences, seq_lengths, y=None):
"""
Dataset class for RNN classifiers. The heavy-lifting is done by
`collate_fn`, which handles the padding and packing necessary to
efficiently process variable length sequences.
Parameters
----------
sequences : list of `torch.LongTensor`, `len(n_examples)`
seq_lengths : torch.LongTensor, shape `(n_examples, )`
y : None or torch.LongTensor, shape `(n_examples, )`
If None, then we are in prediction mode. Otherwise, these are
indices into the list of classes.
"""
assert len(sequences) == len(seq_lengths)
self.sequences = sequences
self.seq_lengths = seq_lengths
if y is not None:
assert len(sequences) == len(y)
self.y = y
@staticmethod
def collate_fn(batch):
"""
Format a batch of examples for use in both training and prediction.
Parameters
----------
batch : tuple of length 2 (prediction) or 3 (training)
The first element is the list of input sequences. The
second is the list of lengths for those sequences. The third,
where present, is the list of labels.
Returns
-------
X : torch.Tensor, shape `(batch_size, max_batch_length)`
As padded by `torch.nn.utils.rnn.pad_sequence.
seq_lengths : torch.LongTensor, shape `(batch_size, )`
y : torch.LongTensor, shape `(batch_size, )`
Only for training. In the case where `y` cannot be turned into
a Tensor, we assume it is because it is a list of variable
length sequences and to use `torch.nn.utils.rnn.pad_sequence`.
The hope is that this will accomodate sequence prediction.
"""
batch_elements = list(zip(*batch))
X = batch_elements[0]
seq_lengths = batch_elements[1]
X = torch.nn.utils.rnn.pad_sequence(X, batch_first=True)
seq_lengths = torch.tensor(seq_lengths)
if len(batch_elements) == 3:
y = batch_elements[2]
# We can try to accommodate the case where `y` is a sequence
# loss with potentially different lengths by resorting to
# padding if creating a tensor is not possible:
try:
y = torch.tensor(y)
except (ValueError, TypeError):
y = torch.nn.utils.rnn.pad_sequence(y, batch_first=True)
return X, seq_lengths, y
else:
return X, seq_lengths
def __len__(self):
return len(self.sequences)
def __getitem__(self, idx):
if self.y is not None:
return self.sequences[idx], self.seq_lengths[idx], self.y[idx]
else:
return self.sequences[idx], self.seq_lengths[idx]
class TorchRNNModel(nn.Module):
def __init__(self,
vocab_size,
embed_dim=50,
embedding=None,
use_embedding=True,
rnn_cell_class=nn.LSTM,
hidden_dim=50,
bidirectional=False,
freeze_embedding=False):
"""
Defines the core RNN computation graph. For an explanation of the
parameters, see `TorchRNNClassifierModel`. This class handles just
the RNN components of the overall classifier model.
`TorchRNNClassifierModel` uses the output states to create a
classifier.
"""
super().__init__()
self.vocab_size = vocab_size
self.use_embedding = use_embedding
self.embed_dim = embed_dim
self.hidden_dim = hidden_dim
self.bidirectional = bidirectional
self.freeze_embedding = freeze_embedding
# Graph
if self.use_embedding:
self.embedding = self._define_embedding(
embedding, vocab_size, self.embed_dim, self.freeze_embedding)
self.embed_dim = self.embedding.embedding_dim
self.rnn = rnn_cell_class(
input_size=self.embed_dim,
hidden_size=hidden_dim,
batch_first=True,
bidirectional=bidirectional)
def forward(self, X, seq_lengths):
if self.use_embedding:
X = self.embedding(X)
embs = torch.nn.utils.rnn.pack_padded_sequence(
X,
batch_first=True,
lengths=seq_lengths.cpu(),
enforce_sorted=False)
outputs, state = self.rnn(embs)
return outputs, state
@staticmethod
def _define_embedding(embedding, vocab_size, embed_dim, freeze_embedding):
if embedding is None:
emb = nn.Embedding(vocab_size, embed_dim)
emb.weight.requires_grad = not freeze_embedding
return emb
elif isinstance(embedding, np.ndarray):
embedding = torch.FloatTensor(embedding)
return nn.Embedding.from_pretrained(
embedding, freeze=freeze_embedding)
else:
return embedding
class TorchRNNClassifierModel(nn.Module):
def __init__(self, rnn, output_dim, classifier_activation):
"""
Defines the core computation graph for `TorchRNNClassifier`. This
involves using the outputs of a `TorchRNNModel` instance to
build a softmax classifier:
h[t] = rnn(x[t], h[t-1])
h = f(h[-1].dot(W_hy) + b_h)
y = softmax(hW + b_y)
This class uses its `rnn` parameter to compute each `h[1]`, and
then it adds the classifier parameters that use `h[-1]` as inputs.
Where `bidirectional=True`, `h[-1]` is `torch.cat([h[0], h[-1])`.
"""
super().__init__()
self.rnn = rnn
self.output_dim = output_dim
self.hidden_dim = self.rnn.hidden_dim
if self.rnn.bidirectional:
self.classifier_dim = self.hidden_dim * 2
else:
self.classifier_dim = self.hidden_dim
self.hidden_layer = nn.Linear(
self.classifier_dim, self.hidden_dim)
self.classifier_activation = classifier_activation
self.classifier_layer = nn.Linear(
self.hidden_dim, self.output_dim)
def forward(self, X, seq_lengths):
outputs, state = self.rnn(X, seq_lengths)
state = self.get_batch_final_states(state)
if self.rnn.bidirectional:
state = torch.cat((state[0], state[1]), dim=1)
h = self.classifier_activation(self.hidden_layer(state))
logits = self.classifier_layer(h)
return logits
def get_batch_final_states(self, state):
if self.rnn.rnn.__class__.__name__ == 'LSTM':
return state[0].squeeze(0)
else:
return state.squeeze(0)
class TorchRNNClassifier(TorchModelBase):
def __init__(self,
vocab,
hidden_dim=50,
embedding=None,
use_embedding=True,
embed_dim=50,
rnn_cell_class=nn.LSTM,
bidirectional=False,
freeze_embedding=False,
classifier_activation=nn.ReLU(),
**base_kwargs):
"""
RNN-based Recurrent Neural Network for classification problems.
The network will work for any kind of classification task.
Parameters
----------
vocab : list of str
This should be the vocabulary. It needs to be aligned with
`embedding` in the sense that the ith element of vocab
should be represented by the ith row of `embedding`. Ignored
if `use_embedding=False`.
embedding : np.array or None
Each row represents a word in `vocab`, as described above.
use_embedding : bool
If True, then incoming examples are presumed to be lists of
elements of the vocabulary. If False, then they are presumed
to be lists of vectors. In this case, the `embedding` and
`embed_dim` arguments are ignored, since no embedding is needed
and `embed_dim` is set by the nature of the incoming vectors.
embed_dim : int
Dimensionality for the initial embeddings. This is ignored
if `embedding` is not None, as a specified value there
determines this value. Also ignored if `use_embedding=False`.
rnn_cell_class : class for PyTorch recurrent layer
Should be just the class name, not an instance of the class.
hidden_dim : int
Dimensionality of the hidden layer in the RNN.
bidirectional : bool
If True, then the final hidden states from passes in both
directions are used.
freeze_embedding : bool
If True, the embedding will be updated during training. If
False, the embedding will be frozen. This parameter applies
to both randomly initialized and pretrained embeddings.
classifier_activation : nn.Module
The non-activation function used by the network for the
hidden layer of the classifier.
**base_kwargs
For details, see `torch_model_base.py`.
Attributes
----------
loss: nn.CrossEntropyLoss(reduction="mean")
self.params: list
Extends TorchModelBase.params with names for all of the
arguments for this class to support tuning of these values
using `sklearn.model_selection` tools.
"""
self.vocab = vocab
self.hidden_dim = hidden_dim
self.embedding = embedding
self.use_embedding = use_embedding
self.embed_dim = embed_dim
self.rnn_cell_class = rnn_cell_class
self.bidirectional = bidirectional
self.freeze_embedding = freeze_embedding
self.classifier_activation = classifier_activation
super().__init__(**base_kwargs)
self.params += [
'hidden_dim',
'embed_dim',
'embedding',
'use_embedding',
'rnn_cell_class',
'bidirectional',
'freeze_embedding',
'classifier_activation']
self.loss = nn.CrossEntropyLoss(reduction="mean")
def build_graph(self):
"""
The core computation graph. This is called by `fit`, which sets
the `self.model` attribute.
Returns
-------
TorchRNNModel
"""
rnn = TorchRNNModel(
vocab_size=len(self.vocab),
embedding=self.embedding,
use_embedding=self.use_embedding,
embed_dim=self.embed_dim,
rnn_cell_class=self.rnn_cell_class,
hidden_dim=self.hidden_dim,
bidirectional=self.bidirectional,
freeze_embedding=self.freeze_embedding)
model = TorchRNNClassifierModel(
rnn=rnn,
output_dim=self.n_classes_,
classifier_activation=self.classifier_activation)
self.embed_dim = rnn.embed_dim
return model
def build_dataset(self, X, y=None):
"""
Format data for training and prediction.
Parameters
----------
X : list of lists
The raw sequences. The lists are expected to contain
elements of `self.vocab`. This method converts them to
indices for PyTorch.
y : list or None
The raw labels. This method turns them into indices for
PyTorch processing. If None, then we are in prediction
mode.
Returns
-------
TorchRNNDataset
"""
X, seq_lengths = self._prepare_sequences(X)
if y is None:
return TorchRNNDataset(X, seq_lengths)
else:
self.classes_ = sorted(set(y))
self.n_classes_ = len(self.classes_)
class2index = dict(zip(self.classes_, range(self.n_classes_)))
y = [class2index[label] for label in y]
return TorchRNNDataset(X, seq_lengths, y)
def _prepare_sequences(self, X):
"""
Internal method for turning X into a list of indices into
`self.vocab` and calculating the true lengths of the elements
in `X`.
Parameters
----------
X : list of lists, `len(n_examples)`
Returns
-------
new_X : list of lists, `len(n_examples)`
seq_lengths : torch.LongTensor, shape `(n_examples, )`
"""
if self.use_embedding:
new_X = []
seq_lengths = []
index = dict(zip(self.vocab, range(len(self.vocab))))
unk_index = index['$UNK']
for ex in X:
seq = [index.get(w, unk_index) for w in ex]
seq = torch.tensor(seq)
new_X.append(seq)
seq_lengths.append(len(seq))
else:
new_X = [torch.FloatTensor(ex) for ex in X]
seq_lengths = [len(ex) for ex in X]
self.embed_dim = X[0][0].shape[0]
seq_lengths = torch.tensor(seq_lengths)
return new_X, seq_lengths
def score(self, X, y, device=None):
"""
Uses macro-F1 as the score function. Note: this departs from
`sklearn`, where classifiers use accuracy as their scoring
function. Using macro-F1 is more consistent with our course.
This function can be used to evaluate models, but its primary
use is in cross-validation and hyperparameter tuning.
Parameters
----------
X: np.array, shape `(n_examples, n_features)`
y: iterable, shape `len(n_examples)`
These can be the raw labels. They will converted internally
as needed. See `build_dataset`.
device: str or None
Allows the user to temporarily change the device used
during prediction. This is useful if predictions require a
lot of memory and so are better done on the CPU. After
prediction is done, the model is returned to `self.device`.
Returns
-------
float
"""
preds = self.predict(X, device=device)
return utils.safe_macro_f1(y, preds)
def predict_proba(self, X, device=None):
"""
Predicted probabilities for the examples in `X`.
Parameters
----------
X : np.array, shape `(n_examples, n_features)`
device: str or None
Allows the user to temporarily change the device used
during prediction. This is useful if predictions require a
lot of memory and so are better done on the CPU. After
prediction is done, the model is returned to `self.device`.
Returns
-------
np.array, shape `(len(X), self.n_classes_)`
Each row of this matrix will sum to 1.0.
"""
preds = self._predict(X, device=device)
probs = torch.softmax(preds, dim=1).cpu().numpy()
return probs
def predict(self, X, device=None):
"""
Predicted labels for the examples in `X`. These are converted
from the integers that PyTorch needs back to their original
values in `self.classes_`.
Parameters
----------
X : np.array, shape `(n_examples, n_features)`
device: str or None
Allows the user to temporarily change the device used
during prediction. This is useful if predictions require a
lot of memory and so are better done on the CPU. After
prediction is done, the model is returned to `self.device`.
Returns
-------
list, length len(X)
"""
probs = self.predict_proba(X, device=device)
return [self.classes_[i] for i in probs.argmax(axis=1)]
def simple_example():
utils.fix_random_seeds()
vocab = ['a', 'b', '$UNK']
# No b before an a
train = [
[list('ab'), 'good'],
[list('aab'), 'good'],
[list('abb'), 'good'],
[list('aabb'), 'good'],
[list('ba'), 'bad'],
[list('baa'), 'bad'],
[list('bba'), 'bad'],
[list('bbaa'), 'bad'],
[list('aba'), 'bad']]
test = [
[list('baaa'), 'bad'],
[list('abaa'), 'bad'],
[list('bbaa'), 'bad'],
[list('aaab'), 'good'],
[list('aaabb'), 'good']]
X_train, y_train = zip(*train)
X_test, y_test = zip(*test)
mod = TorchRNNClassifier(vocab)
print(mod)
mod.fit(X_train, y_train)
preds = mod.predict(X_test)
print("\nPredictions:")
for ex, pred, gold in zip(X_test, preds, y_test):
score = "correct" if pred == gold else "incorrect"
print("{0:>6} - predicted: {1:>4}; actual: {2:>4} - {3}".format(
"".join(ex), pred, gold, score))
return mod.score(X_test, y_test)
if __name__ == '__main__':
simple_example()