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torch_color_describer.py
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torch_color_describer.py
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import copy
import itertools
import nltk.translate.bleu_score
import numpy as np
import random
from sklearn.metrics import accuracy_score
import torch
import torch.nn as nn
import torch.utils.data
from torch_model_base import TorchModelBase
import utils
from utils import START_SYMBOL, END_SYMBOL, UNK_SYMBOL
__author__ = "Christopher Potts"
__version__ = "CS224u, Stanford, Spring 2022"
class ColorDataset(torch.utils.data.Dataset):
"""
PyTorch dataset for contextual color describers. The primary
function of this dataset is to organize the raw data into
batches of Tensors of the appropriate shape and type. When
using this dataset with `torch.utils.data.DataLoader`, it is
crucial to supply the `collate_fn` method as the argument for
the `DataLoader.collate_fn` parameter.
Parameters
----------
color_seqs : list of lists of lists of floats, or np.array
Dimension (m, n, p) where m is the number of examples, n is
the number of colors in each context, and p is the length
of the color representations.
word_seqs : list of list of int
Dimension m, the number of examples. The length of each
sequence can vary.
ex_lengths : list of int
Dimension m. Each value gives the length of the corresponding
word sequence in `word_seqs`.
"""
def __init__(self, color_seqs, word_seqs, ex_lengths):
assert len(color_seqs) == len(ex_lengths)
assert len(color_seqs) == len(word_seqs)
self.color_seqs = color_seqs
self.word_seqs = word_seqs
self.ex_lengths = ex_lengths
@staticmethod
def collate_fn(batch):
"""
Function for creating batches.
Parameter
---------
batch : tuple of length 3
Contains the `color_seqs`, `word_seqs`, and `ex_lengths`,
all as lists or similar Python iterables. The function
turns them into Tensors.
Returns
-------
color_seqs : torch.FloatTensor.
The shape is `(m, n, p)` where `m` is the batch_size,
`n` is the number of colors in each context, and `p` is
the color dimensionality.
word_seqs : torch.LongTensor
This is a padded sequence, dimension (m, k), where `m` is
the batch_size and `k` is the length of the longest sequence
in the batch.
ex_lengths : torch.LongTensor
The true lengths of each sequence in `word_seqs. This will
have shape `(m, )`, where `m` is the batch_size.
targets : torch.LongTensor
This is a padded sequence, dimension (m, k-1), where `m` is
the batch_size and `k` is the length of the longest sequence
in the batch. The targets match `word_seqs` except we drop the
first symbol, as it is always START_SYMBOL. When the loss is
calculated, we compare this sequence to `word_seqs` excluding
the final character, which is always the END_SYMBOL. The result
is that each timestep t is trained to predict the symbol
at t+1.
"""
color_seqs, word_seqs, ex_lengths = zip(*batch)
# Conversion to Tensors:
color_seqs = torch.FloatTensor(color_seqs)
word_seqs = [torch.LongTensor(seq) for seq in word_seqs]
ex_lengths = torch.LongTensor(ex_lengths)
# Targets as next-word predictions:
targets = [x[1:, ] for x in word_seqs]
# Padding
word_seqs = torch.nn.utils.rnn.pad_sequence(
word_seqs, batch_first=True)
targets = torch.nn.utils.rnn.pad_sequence(
targets, batch_first=True)
return color_seqs, word_seqs, ex_lengths, targets
def __len__(self):
return len(self.color_seqs)
def __getitem__(self, idx):
return self.color_seqs[idx], self.word_seqs[idx], self.ex_lengths[idx]
class Encoder(nn.Module):
def __init__(self, color_dim, hidden_dim):
"""
Simple Encoder model based on a GRU cell.
Parameters
----------
color_dim : int
hidden_dim : int
"""
super().__init__()
self.color_dim = color_dim
self.hidden_dim = hidden_dim
self.rnn = nn.GRU(
input_size=self.color_dim,
hidden_size=self.hidden_dim,
batch_first=True)
def forward(self, color_seqs):
"""
Parameters
----------
color_seqs : torch.FloatTensor
The shape is `(m, n, p)` where `m` is the batch_size,
`n` is the number of colors in each context, and `p` is
the color dimensionality.
Returns
-------
hidden : torch.FloatTensor
These are the final hidden state of the RNN for this batch,
shape `(m, p) where `m` is the batch_size and `p` is
the color dimensionality.
"""
output, hidden = self.rnn(color_seqs)
return hidden
class Decoder(nn.Module):
def __init__(self,
vocab_size,
embed_dim,
hidden_dim,
embedding=None,
freeze_embedding=False):
"""
Simple Decoder model based on a GRU cell. The hidden
representations of the GRU are passed through a dense linear
layer, and those logits are used to train the language model
according to a softmax objective in `ContextualColorDescriber`.
Parameters
----------
vocab_size : int
embed_dim : int
hidden_dim : int
embedding : np.array or None
If `None`, a random embedding is created. If `np.array`, this
value becomes the embedding.
"""
super().__init__()
self.vocab_size = vocab_size
self.hidden_dim = hidden_dim
self.freeze_embedding = freeze_embedding
self.embedding = self._define_embedding(
embedding, self.vocab_size, embed_dim, self.freeze_embedding)
self.embed_dim = self.embedding.embedding_dim
self.rnn = nn.GRU(
input_size=self.embed_dim,
hidden_size=self.hidden_dim,
batch_first=True)
self.output_layer = nn.Linear(self.hidden_dim, self.vocab_size)
def forward(self, word_seqs, seq_lengths=None, hidden=None, target_colors=None):
"""
Core computation for the model.
Parameters
----------
word_seqs : torch.LongTensor
This is a padded sequence, dimension (m, k), where k is
the length of the longest sequence in the batch. The `forward`
method uses `self.get_embeddings` to map these indices to their
embeddings.
seq_lengths : torch.LongTensor
Shape (m, ) where `m` is the number of examples in the batch.
hidden : torch.FloatTensor
Shape `(m, self.hidden_dim)`. When training, this is always the
final state of the `Encoder`. During prediction, this might be
recursively computed as the sequence is processed.
target_colors : torch.FloatTensor
Dimension (m, c), where m is the number of examples and
c is the dimensionality of the color representations.
Returns
-------
output : torch.FloatTensor
The full sequence of outputs states. When we are training, the
shape is `(m, hidden_dim, k)` to accommodate the expectations
of the loss function. During prediction, the shape is
`(m, k, hidden_dim)`. In both cases, m is the number of examples in
the batch and `k` is the maximum length of sequences in this batch.
hidden : torch.FloatTensor
The final output state of the network. Shape `(m, hidden_dim)`
where m is the number of examples in the batch.
"""
embs = self.get_embeddings(word_seqs, target_colors=target_colors)
if self.training:
# Packed sequence for performance:
embs = torch.nn.utils.rnn.pack_padded_sequence(
embs,
batch_first=True,
lengths=seq_lengths.cpu(),
enforce_sorted=False)
# RNN forward:
output, hidden = self.rnn(embs, hidden)
# Unpack:
output, seq_lengths = torch.nn.utils.rnn.pad_packed_sequence(
output, batch_first=True)
# Output dense layer to get logits:
output = self.output_layer(output)
# Drop the final element:
output = output[:, : -1, :]
# Reshape for the sake of the loss function:
output = output.transpose(1, 2)
return output, hidden
else:
output, hidden = self.rnn(embs, hidden)
output = self.output_layer(output)
return output, hidden
def get_embeddings(self, word_seqs, target_colors=None):
"""
Gets the input token representations. At present, these are
just taken directly from `self.embedding`, but `target_colors`
can be made available in case the user wants to subclass this
function to append these representations to each input token.
Parameters
----------
word_seqs : torch.LongTensor
This is a padded sequence, dimension (m, k), where k is
the length of the longest sequence in the batch.
target_colors : torch.FloatTensor
Dimension (m, c), where m is the number of examples and
c is the dimensionality of the color representations.
"""
return self.embedding(word_seqs)
@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
else:
embedding = torch.FloatTensor(embedding)
return nn.Embedding.from_pretrained(
embedding, freeze=freeze_embedding)
class EncoderDecoder(nn.Module):
def __init__(self, encoder, decoder):
"""
This class knits the `Encoder` and `Decoder` into a single class
that serves as the model for `ContextualColorDescriber`. This is
largely a convenience: it means that `ContextualColorDescriber`
can use a single `model` argument, and it allows us to localize
the core computations in the `forward` method of this class.
Parameters
----------
encoder : `Encoder`
decoder : `Decoder`
"""
super().__init__()
self.encoder = encoder
self.decoder = decoder
def forward(self, color_seqs, word_seqs, seq_lengths, hidden=None):
"""This is the core method for this module. It has a lot of
arguments mainly to make it easy to create subclasses of this
class that do interesting things without requiring modifications
to the `fit` method of `ContextualColorDescriber`.
Parameters
----------
color_seqs : torch.FloatTensor
Dimension (m, n, p), where m is the number of examples,
n is the number of colors in each context, and p is the
dimensionality of each color.
word_seqs : torch.LongTensor
Dimension (m, k), where m is the number of examples and k
is the length of all the (padded) sequences in the batch.
seq_lengths : torch.LongTensor or None
The true lengths of the sequences in `word_seqs`. If this
is None, then we are predicting new sequences, so we will
continue predicting until we hit a maximum length or we
generate STOP_SYMBOL.
hidden : torch.FloatTensor or None
The hidden representation for each of the m examples in this
batch. If this is None, we are predicting new sequences
and so the hidden representation is computed for each timestep
during decoding.
Returns
-------
output : torch.FloatTensor
Dimension (m, k, c), where m is the number of examples, k
is the length of the sequences in this batch, and c is the
number of classes (the size of the vocabulary).
hidden : torch.FloatTensor
Dimension (m, h) where m is the number of examples and h is
the dimensionality of the hidden representations of the model.
This value is returned only when the model is in eval mode.
"""
if hidden is None:
hidden = self.encoder(color_seqs)
output, hidden = self.decoder(
word_seqs, seq_lengths=seq_lengths, hidden=hidden)
if self.training:
return output
else:
return output, hidden
class ContextualColorDescriber(TorchModelBase):
def __init__(self,
vocab,
embedding=None,
embed_dim=50,
hidden_dim=50,
freeze_embedding=False,
**base_kwargs):
"""
The primary interface to modeling contextual colors datasets.
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`.
embedding : np.array or None
Each row represents a word in `vocab`, as described above.
embed_dim : int
Dimensionality for the initial embeddings. This is ignored
if `embedding` is not None, as a specified value there
determines this value.
hidden_dim : int
Dimensionality of the hidden layer.
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.
**base_kwargs
For details, see `torch_model_base.py`.
Attributes
----------
vocab_size : int
word2index : dict
A look-up from vocab items to their indices.
index2word : dict
A look-up for indices to vocab items.
output_dim : int
Same as `vocab_size`.
start_index : int
Index of START_SYMBOL in `self.vocab`.
end_index : int
Index of END_SYMBOL in `self.vocab`.
unk_index : int
Index of UNK_SYMBOL in `self.vocab`.
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.
"""
super().__init__(**base_kwargs)
self.vocab = vocab
self.hidden_dim = hidden_dim
self.embedding = embedding
self.freeze_embedding = freeze_embedding
self.vocab_size = len(vocab)
self.word2index = dict(zip(self.vocab, range(self.vocab_size)))
self.index2word = dict(zip(range(self.vocab_size), self.vocab))
self.embed_dim = embed_dim
self.output_dim = self.vocab_size
self.start_index = self.vocab.index(START_SYMBOL)
self.end_index = self.vocab.index(END_SYMBOL)
self.unk_index = self.vocab.index(UNK_SYMBOL)
self.params += ['hidden_dim', 'embed_dim', 'embedding', 'freeze_embedding']
self.loss = nn.CrossEntropyLoss()
def build_dataset(self, color_seqs, word_seqs):
"""
Create a dataset from a list of color contexts and
associated utterances.
Parameters
----------
color_seqs : list of lists of color representations
We assume that each context has the same number of colors,
each with the same shape.
word_seqs : list of lists of utterances
A tokenized list of words. This method uses `self.word2index`
to turn this into a list of lists of indices.
Returns
-------
ColorDataset
"""
self.color_dim = len(color_seqs[0][0])
word_seqs = [[self.word2index.get(w, self.unk_index) for w in seq]
for seq in word_seqs]
ex_lengths = [len(seq) for seq in word_seqs]
return ColorDataset(color_seqs, word_seqs, ex_lengths)
def build_graph(self):
"""
The core computation graph. This method is called by `fit` to set
the `self.model` attribute.
Returns
-------
`EncoderDecoder` built from `Encoder` and `Decoder`
"""
encoder = Encoder(
color_dim=self.color_dim,
hidden_dim=self.hidden_dim)
decoder = Decoder(
vocab_size=self.vocab_size,
embed_dim=self.embed_dim,
embedding=self.embedding,
hidden_dim=self.hidden_dim,
freeze_embedding=self.freeze_embedding)
self.embed_dim = decoder.embed_dim
return EncoderDecoder(encoder, decoder)
def predict(self, color_seqs, max_length=20, device=None):
"""
Predict new sequences based on the color contexts in
`color_seqs`.
Parameters
----------
color_seqs : list of lists of lists of floats, or np.array
Dimension (m, n, p) where m is the number of examples, n is
the number of colors in each context, and p is the length
of the color representations.
max_length : int
Length of the longest sequences to create.
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 of str
"""
device = self.device if device is None else torch.device(device)
color_seqs = torch.FloatTensor(color_seqs)
color_seqs = color_seqs.to(device)
self.model.to(device)
self.model.eval()
preds = []
with torch.no_grad():
# Get the hidden representations from the color contexts:
hidden = self.model.encoder(color_seqs)
# Start with START_SYMBOL for all examples:
decoder_input = [[self.start_index]] * len(color_seqs)
decoder_input = torch.LongTensor(decoder_input)
decoder_input = decoder_input.to(device)
preds.append(decoder_input)
# Now move through the remaiming timesteps using the
# previous timestep to predict the next one:
for i in range(1, max_length):
output, hidden = self.model(
color_seqs=color_seqs,
word_seqs=decoder_input,
seq_lengths=None,
hidden=hidden)
# Always take the highest probability token to
# be the prediction:
p = output.argmax(2)
preds.append(p)
decoder_input = p
# Convert all the predictions from indices to elements of
# `self.vocab`:
preds = torch.cat(preds, axis=1)
preds = [self._convert_predictions(p) for p in preds]
self.model.to(self.device)
return preds
def _convert_predictions(self, pred):
rep = []
for i in pred:
i = i.item()
rep.append(self.index2word[i])
if i == self.end_index:
return rep
return rep
def predict_proba(self, color_seqs, word_seqs, device=None):
"""
Calculate the predicted probabilities of the sequences in
`word_seqs` given the color contexts in `color_seqs`.
Parameters
----------
color_seqs : list of lists of lists of floats, or np.array
Dimension (m, n, p) where m is the number of examples, n is
the number of colors in each context, and p is the length
of the color representations.
word_seqs : list of list of int
Dimension m, the number of examples. The length of each
sequence can vary.
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 of lists of predicted probabilities. In other words,
for each example, at each timestep, there is a probability
distribution over the entire vocabulary.
"""
device = self.device if device is None else torch.device(device)
dataset = self.build_dataset(color_seqs, word_seqs)
dataloader = self._build_dataloader(dataset, shuffle=False)
self.model.to(device)
self.model.eval()
softmax = nn.Softmax(dim=2)
start_probs = np.zeros(self.vocab_size)
start_probs[self.start_index] = 1.0
all_probs = []
with torch.no_grad():
for batch_colors, batch_words, batch_lens, targets in dataloader:
batch_colors = batch_colors.to(device)
batch_words = batch_words.to(device)
batch_lens = batch_lens.to(device)
output, _ = self.model(
color_seqs=batch_colors,
word_seqs=batch_words,
seq_lengths=batch_lens)
probs = softmax(output)
probs = probs.cpu().numpy()
probs = np.insert(probs, 0, start_probs, axis=1)
all_probs += [p[: n] for p, n in zip(probs, batch_lens)]
self.model.to(self.device)
return all_probs
def perplexities(self, color_seqs, word_seqs, device=None):
"""
Compute the perplexity of each sequence in `word_seqs`
given `color_seqs`. For a sequence of conditional probabilities
p1, p2, ..., pN, the perplexity is calculated as
(p1 * p2 * ... * pN)**(-1/N)
Parameters
----------
color_seqs : list of lists of floats, or np.array
Dimension (m, n, p) where m is the number of examples, n is
the number of colors in each context, and p is the length
of the color representations.
word_seqs : list of list of int
Dimension m, the number of examples, and the length of
each sequence can vary.
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 of float
"""
probs = self.predict_proba(color_seqs, word_seqs, device=device)
scores = []
for pred, seq in zip(probs, word_seqs):
# Get the probabilities corresponding to the path `seq`:
s = np.array([t[self.word2index.get(w, self.unk_index)]
for t, w in zip(pred, seq)])
scores.append(s)
perp = [np.prod(s)**(-1/len(s)) for s in scores]
return perp
def listener_predict_one(self, context, seq, device=None):
context = np.array(context)
n_colors = len(context)
# Get all possible context orders:
indices = list(range(n_colors))
orders = [list(x) for x in itertools.permutations(indices)]
# Shuffle the context order list so that the true context
# is in a random place in the list:
random.shuffle(orders)
# All contexts as color sequences:
contexts = [context[x] for x in orders]
# Repeat the single utterance the needed number of times:
seqs = [seq] * len(contexts)
# All perplexities:
perps = self.perplexities(contexts, seqs, device=device)
# Ranking, using `order_indices` rather than colors and
# index sequences to avoid sorting errors from some versions
# of Python:
order_indices = range(len(orders))
ranking = sorted(zip(perps, order_indices))
# Return the minimum perplexity, the chosen color, and the
# index of the chosen color in the original context:
min_perp, order_index = ranking[0]
pred_color = contexts[order_index][-1]
pred_index = orders[order_index][-1]
return min_perp, pred_color, pred_index
def listener_predictions(self, color_seqs, word_seqs, device=None):
"""
Compute the listener predictions of the model for each example.
For the ith example, this is defined as
prediction = max_{c in C_i} P(word_seq[i] | c)
where C_i is every possible permutation of the three colors in
color_seqs[i]. We take the model's prediction to be correct
if it chooses a c in which the target is in the privileged final
position in the color sequence. (There are two such c's, since
the distractors can be in two orders; we give full credit if one
of these two c's is chosen.)
Parameters
----------
color_seqs : list of lists of list of floats, or np.array
Dimension (m, n, p) where m is the number of examples, n is
the number of colors in each context, and p is the length
of the color representations.
word_seqs : list of list of int
Dimension m, the number of examples, and the length of
each sequence can vary.
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
-------
tuple of lists, the first member giving the gold target indices
and the second giving the predicted target indices.
"""
gold = []
predicted = []
correct = 0
for color_seq, word_seq in zip(color_seqs, word_seqs):
target_index = len(color_seq) - 1
min_perp, pred, pred_index = self.listener_predict_one(
color_seq, word_seq, device=device)
gold.append(target_index)
predicted.append(pred_index)
return gold, predicted
def listener_accuracy(self, color_seqs, word_seqs, device=None):
"""
Returns the listener accuracy as calculated based on values
returns by `listener_predictions`.
"""
gold, predicted = self.listener_predictions(
color_seqs, word_seqs, device=device)
return accuracy_score(gold, predicted)
def score(self, color_seqs, word_seqs, device=None):
"""
Alias for `listener_accuracy`. This method is included to
make it easier to use sklearn cross-validators, which expect
a method called `score`.
"""
return self.listener_accuracy(color_seqs, word_seqs, device=device)
def corpus_bleu(self, color_seqs, word_seqs):
"""
Calculate the corpus BLEU score achieved by `model` with respect
to `color_seqs` and `word_seqs`, using just unigrams.
Parameters
----------
color_seqs : list of lists of lists of floats, or np.array
Dimension (m, n, p) where m is the number of examples, n is
the number of colors in each context, and p is the length
of the color representations.
word_seqs : list of lists of utterances
A tokenized list of words.
Returns
-------
tuple consisting of the bleu score (float) and the predictions
as a list of lists of tokens
"""
# Ideally, we would have multiple references for each context,
# but alas we have only one:
refs = [[seq] for seq in word_seqs]
# Predict some utterances:
preds = self.predict(color_seqs)
# Calculate a unigrams-only BLEU score:
bleu = nltk.translate.bleu_score.corpus_bleu(
refs, preds, weights=(1, ))
return bleu, preds
def evaluate(self, color_seqs, word_seqs, device=None):
"""
Full evaluation for the bake-off. Uses `listener_accuracy`
and colors_corpus_bleu`.
Parameters
----------
color_seqs : list of lists of lists of floats, or np.array
Dimension (m, n, p) where m is the number of examples, n is
the number of colors in each context, and p is the length
of the color representations.
word_seqs : list of lists of utterances
A tokenized list of words.
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
-------
dict, {
"listener_accuracy": float,
"corpus_bleu": float,
"target_index": list of int,
"predicted_index": list of int}
"""
gold, predicted = self.listener_predictions(
color_seqs, word_seqs, device=device)
acc = accuracy_score(gold, predicted)
bleu, pred_utt = self.corpus_bleu(color_seqs, word_seqs)
return {
"listener_accuracy": acc,
"corpus_bleu": bleu,
"target_index": gold,
"predicted_index": predicted,
"predicted_utterance": pred_utt}
def create_example_dataset(group_size=100, vec_dim=2):
"""
Creates simple datasets in which the inputs are three-vector
sequences and the outputs are simple character sequences, with
the range of values in the final vector in the input determining
the output sequence. For example, a single input/output pair
will look like this:
[[0.44, 0.51], [0.87, 0.89], [0.1, 0.2]], ['<s>', 'A', '</s>']
The sequences are meaningless, as are their lengths (which were
chosen only to be different from each other).
"""
groups = ((0.0, 0.2), (0.4, 0.6), (0.8, 1.0))
vocab = ['<s>', '</s>', 'A', 'B', '$UNK']
seqs = [
['<s>', 'A', '</s>'],
['<s>', 'A', 'B', '</s>'],
['<s>', 'B', 'A', 'B', 'A', '</s>']]
color_seqs = []
word_seqs = []
for i, ((l, u), seq) in enumerate(zip(groups, seqs)):
dis_indices = list(range(len(groups)))
dis_indices.remove(i)
random.shuffle(dis_indices)
disl1, disu1 = groups[dis_indices[0]]
disl2, disu2 = groups[dis_indices[1]]
for _ in range(group_size):
target = utils.randvec(vec_dim, l, u)
dis1 = utils.randvec(vec_dim, disl1, disu1)
dis2 = utils.randvec(vec_dim, disl2, disu2)
context = [dis1, dis2, target]
color_seqs.append(context)
word_seqs += [seq for _ in range(group_size)]
return color_seqs, word_seqs, vocab
def simple_example(group_size=100, vec_dim=2):
from sklearn.model_selection import train_test_split
utils.fix_random_seeds()
color_seqs, word_seqs, vocab = create_example_dataset(
group_size=group_size, vec_dim=vec_dim)
X_train, X_test, y_train, y_test = train_test_split(
color_seqs, word_seqs)
mod = ContextualColorDescriber(vocab)
print(mod)
mod.fit(X_train, y_train)
preds = mod.predict(X_test)
mod.predict_proba(X_test, y_test)
correct = 0
for y, p in zip(y_test, preds):
correct += int(y == p)
print("\nExact sequence: {} of {} correct".format(correct, len(y_test)))
lis_acc = mod.listener_accuracy(X_test, y_test)
print("\nListener accuracy {}".format(lis_acc))
return lis_acc
if __name__ == '__main__':
simple_example()