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np_rnn_classifier.py
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np_rnn_classifier.py
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from collections import OrderedDict
import numpy as np
from np_model_base import NNModelBase
from utils import softmax, safe_macro_f1
__author__ = "Christopher Potts"
__version__ = "CS224u, Stanford, Spring 2022"
class RNNClassifier(NNModelBase):
"""
Simple Recurrent Neural Network for classification problems.
The structure of the network is as follows:
y
/|
b | W_hy
|
h_0 -- W_hh -- h_1 -- W_hh -- h_2 -- W_hh -- h_3
| | |
| W_xh | W_xh | W_xh
| | |
x_1 x_2 x_3
where x_i are the inputs, h_j are the hidden units, and y is a
one-hot vector indicating the true label for this sequence. The
parameters are W_xh, W_hh, W_hy, and the bias b. The inputs x_i
come from a user-supplied embedding space for the vocabulary. These
can either be random or pretrained. The network equations in brief:
h[t] = tanh(x[t].dot(W_xh) + h[t-1].dot(W_hh))
y = softmax(h[-1].dot(W_hy) + b)
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`.
All of the above are set as attributes. In addition, `self.embed_dim`
is set to the dimensionality of the input representations.
"""
def __init__(self,
vocab,
embedding=None,
use_embedding=True,
embed_dim=50,
**kwargs):
self.vocab = vocab
self.vocab_lookup = dict(zip(self.vocab, range(len(self.vocab))))
self.use_embedding = use_embedding
self._embed_dim = embed_dim
if self.use_embedding:
if embedding is None:
embedding = self._define_embedding_matrix(
len(self.vocab), embed_dim)
self.embedding = embedding
self._embed_dim = self.embedding.shape[1]
super().__init__(**kwargs)
self.params += ['embedding', 'embed_dim']
@property
def embed_dim(self):
return self._embed_dim
@embed_dim.setter
def embed_dim(self, value):
self._embed_dim = value
self.embedding = self._define_embedding_matrix(
len(self.vocab), value)
def fit(self, X, y):
if not self.use_embedding:
self._embed_dim = len(X[0][0])
return super().fit(X, y)
def initialize_parameters(self):
"""
Attributes
----------
output_dim : int
Set based on the length of the labels in `training_data`.
This happens in `self.prepare_output_data`.
W_xh : np.array
Dense connections between the word representations
and the hidden layers. Random initialization.
W_hh : np.array
Dense connections between the hidden representations.
Random initialization.
W_hy : np.array
Dense connections from the final hidden layer to
the output layer. Random initialization.
b : np.array
Output bias. Initialized to all 0.
"""
self.W_xh = self.weight_init(self.embed_dim, self.hidden_dim)
self.W_hh = self.weight_init(self.hidden_dim, self.hidden_dim)
self.W_hy = self.weight_init(self.hidden_dim, self.output_dim)
self.b = np.zeros(self.output_dim)
def forward_propagation(self, seq):
"""
Parameters
----------
seq : list
Variable length sequence of elements in the vocabulary.
Returns
----------
h : np.array
Each row is for a hidden representation. The first row
is an all-0 initial state. The others correspond to
the inputs in seq.
y : np.array
The vector of predictions.
"""
h = np.zeros((len(seq)+1, self.hidden_dim))
for t in range(1, len(seq)+1):
if self.use_embedding:
word_rep = self.get_word_rep(seq[t-1])
else:
word_rep = seq[t-1]
h[t] = self.hidden_activation(
word_rep.dot(self.W_xh) + h[t-1].dot(self.W_hh))
y = softmax(h[-1].dot(self.W_hy) + self.b)
return h, y
def backward_propagation(self, h, predictions, seq, labels):
"""
Parameters
----------
h : np.array, shape (m, self.hidden_dim)
Matrix of hidden states. `m` is the shape of the current
example (which is allowed to vary).
predictions : np.array, dimension `len(self.classes)`
Vector of predictions.
seq : list of lists
The original example.
labels : np.array, dimension `len(self.classes)`
One-hot vector giving the true label.
Returns
-------
tuple
The matrices of derivatives (d_W_hy, d_b, d_W_hh, d_W_xh).
"""
# Output errors:
y_err = predictions
y_err[np.argmax(labels)] -= 1
h_err = y_err.dot(self.W_hy.T) * self.d_hidden_activation(h[-1])
d_W_hy = np.outer(h[-1], y_err)
d_b = y_err
# For accumulating the gradients through time:
d_W_hh = np.zeros(self.W_hh.shape)
d_W_xh = np.zeros(self.W_xh.shape)
# Back-prop through time; the +1 is because the 0th
# hidden state is the all-0s initial state.
num_steps = len(seq)+1
for t in reversed(range(1, num_steps)):
d_W_hh += np.outer(h[t], h_err)
if self.use_embedding:
word_rep = self.get_word_rep(seq[t-1])
else:
word_rep = seq[t-1]
d_W_xh += np.outer(word_rep, h_err)
h_err = h_err.dot(self.W_hh.T) * self.d_hidden_activation(h[t])
return (d_W_hy, d_b, d_W_hh, d_W_xh)
def update_parameters(self, gradients):
d_W_hy, d_b, d_W_hh, d_W_xh = gradients
self.W_hy -= self.eta * d_W_hy
self.b -= self.eta * d_b
self.W_hh -= self.eta * d_W_hh
self.W_xh -= self.eta * d_W_xh
def score(self, X, y):
preds = self.predict(X)
return safe_macro_f1(y, preds)
def simple_example():
from sklearn.metrics import accuracy_score
import utils
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 = RNNClassifier(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 accuracy_score(y_test, preds)
if __name__ == '__main__':
simple_example()