forked from dmlc/dgl
-
Notifications
You must be signed in to change notification settings - Fork 0
/
dataset.py
90 lines (81 loc) · 3.34 KB
/
dataset.py
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
import torch
import numpy as np
import dgl
import dgl.function as fn
from ogb.nodeproppred import DglNodePropPredDataset, Evaluator
def get_ogb_evaluator(dataset):
"""
Get evaluator from Open Graph Benchmark based on dataset
"""
evaluator = Evaluator(name=dataset)
return lambda preds, labels: evaluator.eval({
"y_true": labels.view(-1, 1),
"y_pred": preds.view(-1, 1),
})["acc"]
def convert_mag_to_homograph(g, device):
"""
Featurize node types that don't have input features (i.e. author,
institution, field_of_study) by averaging their neighbor features.
Then convert the graph to a undirected homogeneous graph.
"""
src_writes, dst_writes = g.all_edges(etype="writes")
src_topic, dst_topic = g.all_edges(etype="has_topic")
src_aff, dst_aff = g.all_edges(etype="affiliated_with")
new_g = dgl.heterograph({
("paper", "written", "author"): (dst_writes, src_writes),
("paper", "has_topic", "field"): (src_topic, dst_topic),
("author", "aff", "inst"): (src_aff, dst_aff)
})
new_g = new_g.to(device)
new_g.nodes["paper"].data["feat"] = g.nodes["paper"].data["feat"]
new_g["written"].update_all(fn.copy_u("feat", "m"), fn.mean("m", "feat"))
new_g["has_topic"].update_all(fn.copy_u("feat", "m"), fn.mean("m", "feat"))
new_g["aff"].update_all(fn.copy_u("feat", "m"), fn.mean("m", "feat"))
g.nodes["author"].data["feat"] = new_g.nodes["author"].data["feat"]
g.nodes["institution"].data["feat"] = new_g.nodes["inst"].data["feat"]
g.nodes["field_of_study"].data["feat"] = new_g.nodes["field"].data["feat"]
# Convert to homogeneous graph
# Get DGL type id for paper type
target_type_id = g.get_ntype_id("paper")
g = dgl.to_homogeneous(g, ndata=["feat"])
g = dgl.add_reverse_edges(g, copy_ndata=True)
# Mask for paper nodes
g.ndata["target_mask"] = g.ndata[dgl.NTYPE] == target_type_id
return g
def load_dataset(name, device):
"""
Load dataset and move graph and features to device
"""
if name not in ["ogbn-products", "ogbn-arxiv", "ogbn-mag"]:
raise RuntimeError("Dataset {} is not supported".format(name))
dataset = DglNodePropPredDataset(name=name)
splitted_idx = dataset.get_idx_split()
train_nid = splitted_idx["train"]
val_nid = splitted_idx["valid"]
test_nid = splitted_idx["test"]
g, labels = dataset[0]
g = g.to(device)
if name == "ogbn-arxiv":
g = dgl.add_reverse_edges(g, copy_ndata=True)
g = dgl.add_self_loop(g)
g.ndata['feat'] = g.ndata['feat'].float()
elif name == "ogbn-mag":
# MAG is a heterogeneous graph. The task is to make prediction for
# paper nodes
labels = labels["paper"]
train_nid = train_nid["paper"]
val_nid = val_nid["paper"]
test_nid = test_nid["paper"]
g = convert_mag_to_homograph(g, device)
else:
g.ndata['feat'] = g.ndata['feat'].float()
n_classes = dataset.num_classes
labels = labels.squeeze()
evaluator = get_ogb_evaluator(name)
print(f"# Nodes: {g.number_of_nodes()}\n"
f"# Edges: {g.number_of_edges()}\n"
f"# Train: {len(train_nid)}\n"
f"# Val: {len(val_nid)}\n"
f"# Test: {len(test_nid)}\n"
f"# Classes: {n_classes}")
return g, labels, n_classes, train_nid, val_nid, test_nid, evaluator