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This follows the notebook-style split on every run, then trains a stronger
pair-level LightGBM model using graph, content, coauthor, citation, and optional
GNN score features.
"""
from __future__ import annotations
import argparse
import importlib.util
import pickle as pkl
from pathlib import Path
import lightgbm as lgb
import numpy as np
import pandas as pd
from sklearn.metrics import precision_recall_curve, roc_auc_score
def load_train_module(path: Path):
spec = importlib.util.spec_from_file_location("train_val_lgcn_ensemble", path)
module = importlib.util.module_from_spec(spec)
assert spec.loader is not None
spec.loader.exec_module(module)
return module
def read_txt(path: Path):
return [list(map(int, line.strip().split())) for line in path.open()]
def best_f1(y, s):
p, r, t = precision_recall_curve(y, s)
f = 2 * p * r / (p + r + 1e-12)
i = int(np.argmax(f))
return float(f[i]), float(t[i] if i < len(t) else 0.5), float(roc_auc_score(y, s))
def rank01(x):
order = np.argsort(x, kind="mergesort")
out = np.empty(len(x), dtype=np.float32)
out[order] = np.linspace(0, 1, len(x), dtype=np.float32)
return out
class FeatureBuilder:
def __init__(self, root: Path, train_refs: pd.DataFrame):
self.root = root
data_dir = root / "data_and_docs"
self.train = train_refs[["source", "target"]].to_numpy(np.int64)
self.citation = np.array(read_txt(data_dir / "paper_file_ann.txt"), dtype=np.int64)
self.coauthor = np.array(read_txt(data_dir / "author_file_ann.txt"), dtype=np.int64)
with (data_dir / "feature.pkl").open("rb") as f:
feat = pkl.load(f).numpy().astype(np.float32)
feat = feat / (np.linalg.norm(feat, axis=1, keepdims=True) + 1e-8)
self.paper_feat = feat
self.n_author = 6611
self.n_paper = 79937
self.author_deg = np.zeros(self.n_author, np.float32)
self.paper_deg = np.zeros(self.n_paper, np.float32)
for a, p in self.train:
self.author_deg[a] += 1
self.paper_deg[p] += 1
self.cite_out = np.zeros(self.n_paper, np.float32)
self.cite_in = np.zeros(self.n_paper, np.float32)
for s, t in self.citation:
self.cite_out[s] += 1
self.cite_in[t] += 1
self.author_papers = [[] for _ in range(self.n_author)]
for a, p in self.train:
self.author_papers[a].append(p)
self.author_profile = np.zeros((self.n_author, feat.shape[1]), np.float32)
self.author_max_pop = np.zeros(self.n_author, np.float32)
self.author_mean_pop = np.zeros(self.n_author, np.float32)
for a, papers in enumerate(self.author_papers):
if papers:
pf = feat[np.array(papers)]
self.author_profile[a] = pf.mean(axis=0)
n = np.linalg.norm(self.author_profile[a])
if n > 0:
self.author_profile[a] /= n
pops = self.paper_deg[np.array(papers)]
self.author_max_pop[a] = pops.max()
self.author_mean_pop[a] = pops.mean()
self.train_set = set(map(tuple, self.train.tolist()))
self.coauthors = [set() for _ in range(self.n_author)]
for a, b in self.coauthor:
self.coauthors[a].add(b)
self.coauthors[b].add(a)
self.coauthor_read = [set() for _ in range(self.n_author)]
for a in range(self.n_author):
s = set()
for c in self.coauthors[a]:
s.update(self.author_papers[c])
self.coauthor_read[a] = s
self.cites = [set() for _ in range(self.n_paper)]
self.cited_by = [set() for _ in range(self.n_paper)]
for s, t in self.citation:
self.cites[s].add(t)
self.cited_by[t].add(s)
def sample_train_pairs(self, n_pos: int, neg_per_pos: int, seed: int, forbidden_pairs: set[tuple[int, int]] | None = None):
rng = np.random.default_rng(seed)
pos_idx = rng.choice(len(self.train), size=min(n_pos, len(self.train)), replace=False)
pos = self.train[pos_idx]
neg = []
authors = pos[:, 0]
forbidden = self.train_set if forbidden_pairs is None else forbidden_pairs
popular = np.flatnonzero(self.paper_deg >= np.percentile(self.paper_deg[self.paper_deg > 0], 70))
while len(neg) < len(pos) * neg_per_pos:
a = int(authors[len(neg) % len(authors)])
if rng.random() < 0.35 and self.coauthor_read[a]:
p = int(rng.choice(list(self.coauthor_read[a])))
elif rng.random() < 0.70:
# Popular hard negative.
p = int(rng.choice(popular))
else:
p = int(rng.integers(0, self.n_paper))
if (a, p) not in forbidden:
neg.append((a, p))
X_pairs = np.vstack([pos, np.array(neg, dtype=np.int64)])
y = np.concatenate([np.ones(len(pos), np.int8), np.zeros(len(neg), np.int8)])
return X_pairs, y
def sample_task_pairs(
self,
positives: np.ndarray,
n_pos: int,
neg_per_pos: int,
seed: int,
forbidden_pairs: set[tuple[int, int]],
):
rng = np.random.default_rng(seed)
pos_idx = rng.choice(len(positives), size=min(n_pos, len(positives)), replace=False)
pos = positives[pos_idx].astype(np.int64, copy=False)
neg = []
authors = pos[:, 0]
positive_deg_papers = np.flatnonzero(self.paper_deg > 0)
if len(positive_deg_papers) == 0:
positive_deg_papers = np.arange(self.n_paper)
popular_cut = np.percentile(self.paper_deg[positive_deg_papers], 70)
popular = np.flatnonzero(self.paper_deg >= popular_cut)
while len(neg) < len(pos) * neg_per_pos:
a = int(authors[len(neg) % len(authors)])
r = rng.random()
if r < 0.45 and self.coauthor_read[a]:
p = int(rng.choice(list(self.coauthor_read[a])))
elif r < 0.85 and len(popular):
p = int(rng.choice(popular))
else:
p = int(rng.integers(0, self.n_paper))
if (a, p) not in forbidden_pairs:
neg.append((a, p))
X_pairs = np.vstack([pos, np.array(neg, dtype=np.int64)])
y = np.concatenate([np.ones(len(pos), np.int8), np.zeros(len(neg), np.int8)])
return X_pairs, y
def transform(self, pairs: np.ndarray):
n = len(pairs)
out = np.zeros((n, 22), dtype=np.float32)
for i, (a, p) in enumerate(pairs):
papers = self.author_papers[a]
out[i, 0] = np.log1p(self.author_deg[a])
out[i, 1] = np.log1p(self.paper_deg[p])
out[i, 2] = np.log1p(self.cite_in[p])
out[i, 3] = np.log1p(self.cite_out[p])
out[i, 4] = np.log1p(len(self.coauthors[a]))
out[i, 5] = self.paper_deg[p] / (self.author_mean_pop[a] + 1.0)
out[i, 6] = self.paper_deg[p] / (self.author_max_pop[a] + 1.0)
out[i, 7] = float(p in self.coauthor_read[a])
out[i, 8] = np.log1p(sum(1 for c in self.coauthors[a] if p in self.author_papers[c]))
out[i, 9] = float((a, p) in self.train_set)
out[i, 10] = float(self.author_profile[a].dot(self.paper_feat[p]))
if papers:
arr = np.array(papers, dtype=np.int64)
sims = self.paper_feat[arr] @ self.paper_feat[p]
out[i, 11] = float(sims.max())
out[i, 12] = float(sims.mean())
out[i, 13] = float(np.percentile(sims, 90))
# Citation proximity between candidate and author's history.
cand_cites = self.cites[p]
cand_cited_by = self.cited_by[p]
hist = set(papers)
out[i, 14] = np.log1p(len(cand_cites & hist))
out[i, 15] = np.log1p(len(cand_cited_by & hist))
total_neighbors = set()
for hp in papers[:80]:
total_neighbors.update(self.cites[hp])
total_neighbors.update(self.cited_by[hp])
out[i, 16] = float(p in total_neighbors)
out[i, 17] = np.log1p(len(total_neighbors & cand_cites))
out[i, 18] = np.log1p(len(total_neighbors & cand_cited_by))
out[i, 19] = np.log1p(len(papers))
out[i, 20] = self.cite_in[p] / (self.paper_deg[p] + 1.0)
out[i, 21] = self.cite_out[p] / (self.paper_deg[p] + 1.0)
return out
def main():
parser = argparse.ArgumentParser()
parser.add_argument("--package-root", type=Path, default=Path(__file__).resolve().parents[1])
parser.add_argument("--split-seed", type=int, required=True)
parser.add_argument("--train-frac", type=float, default=0.9)
parser.add_argument("--n-pos", type=int, default=250000)
parser.add_argument("--neg-per-pos", type=int, default=3)
parser.add_argument("--inner-holdout-frac", type=float, default=0.12)
parser.add_argument("--gnn-run", action="append", default=[])
args = parser.parse_args()
root = args.package_root
tv = load_train_module(root / "code" / "train_val_lgcn_ensemble.py")
train_refs, val_pairs = tv.make_notebook_style_split(root, args.split_seed, args.train_frac)
rng = np.random.default_rng(args.split_seed + 17001)
mask = rng.random(len(train_refs)) >= args.inner_holdout_frac
support_refs = train_refs.loc[mask].copy()
pseudo_pos = train_refs.loc[~mask, ["source", "target"]].to_numpy(np.int64)
all_train_pairs = set(map(tuple, train_refs[["source", "target"]].to_numpy(np.int64).tolist()))
train_fb = FeatureBuilder(root, support_refs)
eval_fb = FeatureBuilder(root, train_refs)
train_pairs, y_train = train_fb.sample_task_pairs(
pseudo_pos,
args.n_pos,
args.neg_per_pos,
args.split_seed,
all_train_pairs,
)
val_arr = val_pairs[["source", "target"]].to_numpy(np.int64)
y_val = val_pairs["label"].to_numpy(np.int8)
print("computing train features", train_pairs.shape)
X_train = train_fb.transform(train_pairs)
print("computing val features", val_arr.shape)
X_val = eval_fb.transform(val_arr)
# Optional GNN validation score features from dynamic run directories.
for run in args.gnn_run:
score_dir = root / "validation_runs" / f"dynamic_seed{args.split_seed}" / run / "scores"
cols = sorted(score_dir.glob("val_*.npy"))
for c in cols:
s = np.load(c).astype(np.float32)
if len(s) == len(y_val):
X_val = np.column_stack([X_val, s, rank01(s)])
# No train-side GNN scores are available; fill neutral values to let
# validation-only blend be evaluated separately below.
X_train = np.column_stack([X_train, np.zeros(len(X_train), np.float32), np.zeros(len(X_train), np.float32)])
clf = lgb.LGBMClassifier(
n_estimators=1200,
learning_rate=0.025,
num_leaves=63,
max_depth=-1,
subsample=0.85,
colsample_bytree=0.85,
reg_lambda=3.0,
min_child_samples=50,
objective="binary",
verbose=-1,
)
clf.fit(
X_train,
y_train,
eval_set=[(X_val, y_val)],
eval_metric="binary_logloss",
callbacks=[lgb.early_stopping(80, verbose=False)],
)
pred = clf.predict_proba(X_val)[:, 1].astype(np.float32)
f1, th, auc = best_f1(y_val, pred)
out = root / "validation_runs" / f"dynamic_seed{args.split_seed}" / "feature_fusion"
out.mkdir(parents=True, exist_ok=True)
np.save(out / "val_feature_lgb.npy", pred)
pd.DataFrame([{"f1": f1, "threshold": th, "auc": auc, "best_iter": clf.best_iteration_}]).to_csv(out / "result.csv", index=False)
print(f"Feature LGB: f1={f1:.6f} th={th:.6f} auc={auc:.6f} best_iter={clf.best_iteration_}")
if __name__ == "__main__":
main()
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