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sst.py
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import numpy as np
import os
import pandas as pd
from sklearn.model_selection import train_test_split
from sklearn.feature_extraction import DictVectorizer
from sklearn.linear_model import LogisticRegression
from sklearn.metrics import classification_report, f1_score
import scipy.stats
import utils
__author__ = "Christopher Potts"
__version__ = "CS224u, Stanford, Spring 2022"
def sentiment_reader(src_filename, include_subtrees=True, dedup=False):
"""
Iterator for our distribution of the SST-3 and other files in
that format.
Parameters
----------
src_filename : str
Full path to the file to be read.
include_subtrees : bool
If True, then the subtrees are returned as separate examples.
This affects only the train split. For dev and test, only
the full examples are included.
dedup : bool
If True, only one copy of each (example, label) pair is included.
This mainly affects the train set, though there is one repeated
example in the dev set.
Yields
------
pd.DataFrame with columns ['example_id', 'sentence', 'label']
"""
df = pd.read_csv(src_filename)
if not include_subtrees:
df = df[df.is_subtree == 0]
if dedup:
df = df.groupby(['sentence', 'label']).apply(lambda x: x.iloc[0])
df = df.reset_index(drop=True)
return df
def train_reader(sst_home, include_subtrees=False, dedup=False):
"""
Convenience function for reading the SST-3 train file.
"""
src = os.path.join(sst_home, 'sst3-train.csv')
return sentiment_reader(
src, include_subtrees=include_subtrees, dedup=dedup)
def dev_reader(sst_home, include_subtrees=False, dedup=False):
"""
Convenience function for reading the SST-3 dev file.
"""
src = os.path.join(sst_home, 'sst3-dev.csv')
return sentiment_reader(
src, include_subtrees=include_subtrees, dedup=dedup)
def test_reader(sst_home, include_subtrees=False, dedup=False):
"""
Convenience function for reading the SST-3 test file, unlabeled.
This function should be used only for the final stages of a
project, to obtain a submission to be evaluated. If you need
to do an evaluation yourself with the labeled dataset, use
`sentiment_reader` pointing to the labeled version of this
dataset.
"""
src = os.path.join(sst_home, 'sst3-test-unlabeled.csv')
return sentiment_reader(
src, include_subtrees=include_subtrees, dedup=dedup)
def bakeoff_dev_reader(sst_home, include_subtrees=False, dedup=False):
"""
Convenience function for reading the bakeoff dev file.
"""
src = os.path.join(sst_home, 'cs224u-sentiment-dev.csv')
return sentiment_reader(
src, include_subtrees=include_subtrees, dedup=dedup)
def bakeoff_test_reader(sst_home, include_subtrees=False, dedup=False):
"""
Convenience function for reading the bakeoff test file, unlabeled.
"""
src = os.path.join(sst_home, 'cs224u-sentiment-test-unlabeled.csv')
return sentiment_reader(
src, include_subtrees=include_subtrees, dedup=dedup)
def build_dataset(dataframes, phi, vectorizer=None, vectorize=True):
"""
Core general function for building experimental datasets.
Parameters
----------
dataframes : pd.DataFrame or list of pd.DataFrame
The dataset or datasets to process, as read in by
`sentiment_reader`.
phi : feature function
Any function that takes a string as input and returns a
bool/int/float-valued dict as output.
vectorizer : sklearn.feature_extraction.DictVectorizer
If this is None, then a new `DictVectorizer` is created and
used to turn the list of dicts created by `phi` into a
feature matrix. This happens when we are training.
If this is not None, then it's assumed to be a `DictVectorizer`
and used to transform the list of dicts. This happens in
assessment, when we take in new instances and need to
featurize them as we did in training.
vectorize : bool
Whether to use a DictVectorizer. Set this to False for
deep learning models that process their own input.
Returns
-------
dict
A dict with keys 'X' (the feature matrix), 'y' (the list of
labels), 'vectorizer' (the `DictVectorizer`), and
'raw_examples' (the `nltk.Tree` objects, for error analysis).
"""
if isinstance(dataframes, (list, tuple)):
df = pd.concat(dataframes)
else:
df = dataframes
raw_examples = list(df.sentence.values)
feat_dicts = list(df.sentence.apply(phi).values)
if 'label' in df.columns:
labels = list(df.label.values)
else:
labels = None
feat_matrix = None
if vectorize:
# In training, we want a new vectorizer:
if vectorizer is None:
vectorizer = DictVectorizer(sparse=False)
feat_matrix = vectorizer.fit_transform(feat_dicts)
# In assessment, we featurize using the existing vectorizer:
else:
feat_matrix = vectorizer.transform(feat_dicts)
else:
feat_matrix = feat_dicts
return {'X': feat_matrix,
'y': labels,
'vectorizer': vectorizer,
'raw_examples': raw_examples}
def experiment(
train_dataframes,
phi,
train_func,
assess_dataframes=None,
train_size=0.7,
score_func=utils.safe_macro_f1,
vectorize=True,
verbose=True,
random_state=None):
"""
Generic experimental framework. Either assesses with a random
train/test split of `train_reader` or with `assess_reader` if
it is given.
Parameters
----------
train_dataframes : pd.DataFrame or list of pd.DataFrame
The dataset or datasets to process, as read in by
`sentiment_reader`.
phi : feature function
Any function that takes an `nltk.Tree` instance as input
and returns a bool/int/float-valued dict as output.
train_func : model wrapper
Any function that takes a feature matrix and a label list
as its values and returns a fitted model with a `predict`
function that operates on feature matrices.
assess_dataframes : pd.DataFrame, list of pd.DataFrame or None
If None, then the df from `train_dataframes` is split into
a random train/test split, with the the train percentage
determined by `train_size`. If not None, then this should
be a dataset or datasets to process, as read in by
`sentiment_reader`. Each such dataset will be read and
used in a separate evaluation.
train_size : float (default: 0.7)
If `assess_reader` is None, then this is the percentage of
`train_reader` devoted to training. If `assess_reader` is
not None, then this value is ignored.
score_metric : function name (default: `utils.safe_macro_f1`)
This should be an `sklearn.metrics` scoring function. The
default is weighted average F1 (macro-averaged F1). For
comparison with the SST literature, `accuracy_score` might
be used instead. For other metrics that can be used here,
see http://scikit-learn.org/stable/modules/classes.html#module-sklearn.metrics
vectorize : bool
Whether to use a DictVectorizer. Set this to False for
deep learning models that process their own input.
verbose : bool (default: True)
Whether to print out the model assessment to standard output.
Set to False for statistical testing via repeated runs.
random_state : int or None
Optionally set the random seed for consistent sampling
where random train/test splits are being created.
Prints
-------
To standard output, if `verbose=True`
Model precision/recall/F1 report. Accuracy is micro-F1 and is
reported because many SST papers report that figure, but macro
precision/recall/F1 is better given the class imbalances and the
fact that performance across the classes can be highly variable.
Returns
-------
dict with keys
'model': trained model
'phi': the function used for featurization
'train_dataset': a dataset as returned by `build_dataset`
'assess_datasets': list of datasets as returned by `build_dataset`
'predictions': list of lists of predictions on the assessment datasets
'metric': `score_func.__name__`
'score': the `score_func` score on each of the assessment datasets
"""
# Train dataset:
train = build_dataset(
train_dataframes,
phi,
vectorizer=None,
vectorize=vectorize)
# Manage the assessment set-up:
X_train = train['X']
y_train = train['y']
raw_train = train['raw_examples']
assess_datasets = []
if assess_dataframes is None:
X_train, X_assess, y_train, y_assess, raw_train, raw_assess = train_test_split(
X_train, y_train, raw_train,
train_size=train_size,
test_size=None,
random_state=random_state)
assess_datasets.append({
'X': X_assess,
'y': y_assess,
'vectorizer': train['vectorizer'],
'raw_examples': raw_assess})
else:
if not isinstance(assess_dataframes, (tuple, list)):
assess_dataframes = [assess_dataframes]
for assess_df in assess_dataframes:
# Assessment dataset using the training vectorizer:
assess = build_dataset(
assess_df,
phi,
vectorizer=train['vectorizer'],
vectorize=vectorize)
assess_datasets.append(assess)
# Train:
mod = train_func(X_train, y_train)
# Predictions if we have labels:
predictions = []
scores = []
for dataset_num, assess in enumerate(assess_datasets, start=1):
preds = mod.predict(assess['X'])
if assess['y'] is None:
predictions.append(None)
scores.append(None)
else:
if verbose:
if len(assess_datasets) > 1:
print("Assessment dataset {}".format(dataset_num))
print(classification_report(assess['y'], preds, digits=3))
predictions.append(preds)
scores.append(score_func(assess['y'], preds))
true_scores = [s for s in scores if s is not None]
if len(true_scores) > 1 and verbose:
mean_score = np.mean(true_scores)
print("Mean of macro-F1 scores: {0:.03f}".format(mean_score))
# Return the overall scores and other experimental info:
return {
'model': mod,
'phi': phi,
'train_dataset': train,
'assess_datasets': assess_datasets,
'predictions': predictions,
'metric': score_func.__name__,
'scores': scores}
def compare_models(
dataframes,
phi1,
train_func1,
phi2=None,
train_func2=None,
vectorize1=True,
vectorize2=True,
stats_test=scipy.stats.wilcoxon,
trials=10,
train_size=0.7,
score_func=utils.safe_macro_f1):
"""
Wrapper for comparing models. The parameters are like those of
`experiment`, with the same defaults, except
Parameters
----------
dataframes : pd.DataFrame or list of pd.DataFrame
The dataset or datasets to process, as read in by
`sentiment_reader`.
phi1, phi2
Just like `phi` for `experiment`. `phi1` defaults to
`unigrams_phi`. If `phi2` is None, then it is set equal
to `phi1`.
train_func1, train_func2
Just like `train_func` for `experiment`. If `train_func2`
is None, then it is set equal to `train_func`.
vectorize1, vectorize1 : bool
Whether to vectorize the respective inputs. Use `False` for
deep learning models that featurize their own input.
stats_test : scipy.stats function
Defaults to `scipy.stats.wilcoxon`, a non-parametric version
of the paired t-test.
trials : int (default: 10)
Number of runs on random train/test splits of `reader`,
with `train_size` controlling the amount of training data.
train_size : float
Percentage of data to use for training.
Prints
------
To standard output
A report of the assessment.
Returns
-------
(np.array, np.array, float)
The first two are the scores from each model (length `trials`),
and the third is the p-value returned by `stats_test`.
"""
if phi2 == None:
phi2 = phi1
if train_func2 == None:
train_func2 = train_func1
experiments1 = [experiment(dataframes,
phi=phi1,
train_func=train_func1,
score_func=score_func,
vectorize=vectorize1,
verbose=False) for _ in range(trials)]
experiments2 = [experiment(dataframes,
phi=phi2,
train_func=train_func2,
score_func=score_func,
vectorize=vectorize2,
verbose=False) for _ in range(trials)]
scores1 = np.array([d['scores'][0] for d in experiments1])
scores2 = np.array([d['scores'][0] for d in experiments2])
# stats_test returns (test_statistic, p-value). We keep just the p-value:
pval = stats_test(scores1, scores2)[1]
# Report:
print('Model 1 mean: {0:.03f}'.format(scores1.mean()))
print('Model 2 mean: {0:.03f}'.format(scores2.mean()))
print('p = {0:.03f}'.format(pval if pval >= 0.001 else 'p < 0.001'))
# Return the scores for later analysis, and the p value:
return scores1, scores2, pval
def build_rnn_dataset(dataframes, tokenizer=lambda s: s.split()):
"""
Given an SST reader, return the dataset as (X, y) training pairs.
Parameters
----------
dataframes : pd.DataFrame or list of pd.DataFrame
The dataset or datasets to process, as read in by
`sentiment_reader`.
tokenizer : function from str to list of str
Defaults to a whitespace tokenizer.
Returns
-------
X, y
Where X is a list of list of str, and y is the output label list.
"""
if isinstance(dataframes, (list, tuple)):
df = pd.concat(dataframes)
else:
df = dataframes
X = list(df.sentence.apply(tokenizer))
y = list(df.label.values)
return X, y