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"""
TODO: save the data with different config
TODO: get stats for the frequency based selection
"""
import json
from itertools import product
import numpy as np
import pandas as pd
import seaborn as sns
from matplotlib import pyplot as plt
from datasets import Dataset
parameters_min_e_freq = [4, 8, 12, 16]
parameters_max_p_freq = [100, 50, 25, 10]
sns.set_theme(style="whitegrid")
# load filtered data
with open(f"data/t_rex.filter.jsonl") as f:
data = Dataset.from_list([json.loads(i) for i in f.read().split('\n') if len(i) > 0])
df_main = data.to_pandas()
def is_entity(token):
return any(i.isupper() for i in token)
def filtering(row, min_freq: int = 3, target: str = "subject"):
if not row['is_entity']:
return True
return row[target] >= min_freq
def main(min_entity_freq, max_pairs_predicate, min_pairs_predicate: int = 3, random_sampling: bool = True):
df = df_main.copy()
# entity frequency filter
c_sub = df.groupby("subject")['title'].count()
c_obj = df.groupby("object")['title'].count()
key = set(list(c_sub.index) + list(c_obj.index))
count = pd.DataFrame([{'entity': k, "subject": c_sub[k] if k in c_sub else 0, "object": c_obj[k] if k in c_obj else 0} for k in key])
count.index = count.pop('entity')
count['is_entity'] = [is_entity(i) for i in count.index]
count['sum'] = count['subject'] + count['object']
count_filter_sub = count[count.apply(lambda x: filtering(x, min_freq=min_entity_freq, target='subject'), axis=1)]['subject']
count_filter_obj = count[count.apply(lambda x: filtering(x, min_freq=min_entity_freq, target='object'), axis=1)]['object']
vocab_sub = set(count_filter_sub.index)
vocab_obj = set(count_filter_obj.index)
df['flag_subject'] = [i in vocab_sub for i in df['subject']]
df['flag_object'] = [i in vocab_obj for i in df['object']]
df['flag'] = df['flag_subject'] & df['flag_object']
df_filter = df[df['flag']]
df_filter.pop("flag")
df_filter.pop("flag_subject")
df_filter.pop("flag_object")
df_filter['count_subject'] = [count_filter_sub.loc[i] for i in df_filter['subject']]
df_filter['count_object'] = [count_filter_obj.loc[i] for i in df_filter['object']]
df_filter['count_sum'] = df_filter['count_subject'] + df_filter['count_object']
# predicate frequency filter
if random_sampling:
df_balanced = pd.concat(
[g if len(g) <= max_pairs_predicate else g.sample(max_pairs_predicate, random_state=0) for _, g in
df_filter.groupby("predicate") if len(g) >= min_pairs_predicate])
else:
df_balanced = pd.concat(
[g if len(g) <= max_pairs_predicate else g.sort_values(by='count_sum', ascending=False).head(max_pairs_predicate) for _, g in
df_filter.groupby("predicate") if len(g) >= min_pairs_predicate])
df_balanced.pop("count_subject")
df_balanced.pop("count_object")
df_balanced.pop("count_sum")
target_data = [i.to_dict() for _, i in df_balanced.iterrows()]
# return distribution
predicate_dist = df_balanced.groupby("predicate")['text'].count().sort_values(ascending=False).to_dict()
entity, count = np.unique(df_balanced['object'].tolist() + df_balanced['subject'].tolist(), return_counts=True)
entity_dist = dict(list(zip(entity.tolist(), count.tolist())))
return predicate_dist, entity_dist, len(df_balanced), target_data
if __name__ == '__main__':
p_dist_full = []
e_dist_full = []
data_size_full = []
config = []
candidates = list(product(parameters_min_e_freq, parameters_max_p_freq))
# run filtering with different configs
for min_e_freq, max_p_freq in candidates:
p_dist, e_dist, data_size, new_data = main(
min_entity_freq=min_e_freq, max_pairs_predicate=max_p_freq, random_sampling=False)
p_dist_full.append(p_dist)
e_dist_full.append(e_dist)
data_size_full.append(data_size)
config.append([min_e_freq, max_p_freq])
# save data
with open(f"data/t_rex.filter.min_entity_{min_e_freq}_max_predicate_{max_p_freq}.jsonl", 'w') as f:
f.write('\n'.join([json.dumps(i) for i in new_data]))
# check statistics
print("- Data Size")
df_size = pd.DataFrame([{"min entity": mef, "max predicate": mpf, "freq": x} for x, (mef, mpf) in zip(data_size_full, candidates)])
df_size = df_size.pivot(index="min entity", columns="max predicate", values="freq")
df_size.index.name = "min entity / max predicate"
df_size_p = pd.DataFrame(
[{"min entity": mef, "max predicate": mpf, "freq": len(x)} for x, (mef, mpf) in zip(p_dist_full, candidates)])
df_size_p = df_size_p.pivot(index="max predicate", columns="min entity", values="freq")
df_size['predicate'] = df_size_p.loc[10]
df_size.to_csv("data/stats.data_size.csv")
print(df_size.to_markdown())
# plot predicate distribution
df_p = pd.DataFrame([dict(enumerate(sorted(p.values(), reverse=True))) for p in p_dist_full]).T
df_p.columns = [f"min entity: {mef}, max predicate: {mpf}" for mef, mpf in candidates]
fig, axes = plt.subplots(2, 2, constrained_layout=True)
fig.suptitle('Predicate Distribution over Different Configurations')
for (x, y), mpf in zip([(0, 0), (0, 1), (1, 0), (1, 1)], [100, 50, 25, 10]):
_df = df_p[[f"min entity: {mef}, max predicate: {mpf}" for mef in [1, 2, 3, 4]]]
_df.columns = [f"min entity: {mef}" for mef in [1, 2, 3, 4]]
ax = sns.lineplot(ax=axes[x, y], data=_df, linewidth=1)
if mpf != 100:
ax.legend_.remove()
axes[x, y].set_title(f'max predicate: {mpf}')
fig.supxlabel('unique predicates sorted by frequency')
fig.supylabel('number of triples')
fig.savefig("data/stats.predicate_distribution.png", bbox_inches='tight')
fig.clf()
# plot entity distribution
df_e = pd.DataFrame([dict(enumerate(sorted(e.values(), reverse=True))) for e in e_dist_full]).T
df_e.columns = [f"min entity: {mef}, max predicate: {mpf}" for mef, mpf in candidates]
fig, axes = plt.subplots(2, 2, constrained_layout=True)
fig.suptitle('Entity Distribution over Different Configurations')
for (x, y), mpf in zip([(0, 0), (0, 1), (1, 0), (1, 1)], [100, 50, 25, 10]):
_df = df_e[[f"min entity: {mef}, max predicate: {mpf}" for mef in [1, 2, 3, 4]]]
_df.columns = [f"min entity: {mef}" for mef in [1, 2, 3, 4]]
ax = sns.lineplot(ax=axes[x, y], data=_df, linewidth=1)
ax.set(xscale='log')
if mpf != 100:
ax.legend_.remove()
axes[x, y].set_title(f'max predicate: {mpf}')
fig.supxlabel('unique entities sorted by frequency')
fig.supylabel('number of triples')
fig.savefig("data/stats.entity_distribution.png", bbox_inches='tight')
fig.clf() |