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2026-07-13 13:35:51 +08:00

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"""
[RGCN: Relational Graph Convolutional Networks]
(https://arxiv.org/abs/1703.06103)
This example showcases the usage of `CuGraphRelGraphConv` via the entity
classification problem in the RGCN paper with mini-batch training. It offers
a 1.5~2x speed-up over `RelGraphConv` on cuda devices and only requires minimal
code changes from the current `entity_sample.py` example.
"""
import argparse
import dgl
import torch
import torch.nn as nn
import torch.nn.functional as F
from dgl.data.rdf import AIFBDataset, AMDataset, BGSDataset, MUTAGDataset
from dgl.dataloading import DataLoader, MultiLayerNeighborSampler
from dgl.nn import CuGraphRelGraphConv
from torchmetrics.functional import accuracy
class RGCN(nn.Module):
def __init__(self, num_nodes, h_dim, out_dim, num_rels, num_bases):
super().__init__()
self.emb = nn.Embedding(num_nodes, h_dim)
# two-layer RGCN
self.conv1 = CuGraphRelGraphConv(
h_dim,
h_dim,
num_rels,
regularizer="basis",
num_bases=num_bases,
self_loop=True,
apply_norm=True,
)
self.conv2 = CuGraphRelGraphConv(
h_dim,
out_dim,
num_rels,
regularizer="basis",
num_bases=num_bases,
self_loop=True,
apply_norm=True,
)
def forward(self, g, fanouts=[None, None]):
x = self.emb(g[0].srcdata[dgl.NID])
h = F.relu(self.conv1(g[0], x, g[0].edata[dgl.ETYPE], fanouts[0]))
h = self.conv2(g[1], h, g[1].edata[dgl.ETYPE], fanouts[1])
return h
def evaluate(model, labels, dataloader, inv_target):
model.eval()
eval_logits = []
eval_seeds = []
with torch.no_grad():
for _, output_nodes, blocks in dataloader:
output_nodes = inv_target[output_nodes.type(torch.int64)]
logits = model(blocks)
eval_logits.append(logits.cpu().detach())
eval_seeds.append(output_nodes.cpu().detach())
num_classes = eval_logits[0].shape[1]
eval_logits = torch.cat(eval_logits)
eval_seeds = torch.cat(eval_seeds)
return accuracy(
eval_logits.argmax(dim=1),
labels[eval_seeds].cpu(),
task="multiclass",
num_classes=num_classes,
).item()
def train(device, g, target_idx, labels, train_mask, model, fanouts):
# Define train idx, loss function and optimizer.
train_idx = torch.nonzero(train_mask, as_tuple=False).squeeze()
loss_fcn = nn.CrossEntropyLoss()
optimizer = torch.optim.Adam(model.parameters(), lr=1e-2, weight_decay=5e-4)
# Construct sampler and dataloader.
sampler = MultiLayerNeighborSampler(fanouts)
train_loader = DataLoader(
g,
target_idx[train_idx].type(g.idtype),
sampler,
device=device,
batch_size=100,
shuffle=True,
)
# No separate validation subset, use train index instead for validation.
val_loader = DataLoader(
g,
target_idx[train_idx].type(g.idtype),
sampler,
device=device,
batch_size=100,
shuffle=False,
)
for epoch in range(50):
model.train()
total_loss = 0
for it, (_, output_nodes, blocks) in enumerate(train_loader):
output_nodes = inv_target[output_nodes.type(torch.int64)]
logits = model(blocks, fanouts=fanouts)
loss = loss_fcn(logits, labels[output_nodes])
optimizer.zero_grad()
loss.backward()
optimizer.step()
total_loss += loss.item()
acc = evaluate(model, labels, val_loader, inv_target)
print(
f"Epoch {epoch:05d} | Loss {total_loss / (it+1):.4f} | "
f"Val. Accuracy {acc:.4f}"
)
if __name__ == "__main__":
parser = argparse.ArgumentParser(
description="RGCN for entity classification with sampling"
)
parser.add_argument(
"--dataset",
type=str,
default="aifb",
choices=["aifb", "mutag", "bgs", "am"],
)
args = parser.parse_args()
device = torch.device("cuda")
print(f"Training with DGL CuGraphRelGraphConv module with sampling.")
# Load and preprocess dataset.
if args.dataset == "aifb":
data = AIFBDataset()
elif args.dataset == "mutag":
data = MUTAGDataset()
elif args.dataset == "bgs":
data = BGSDataset()
elif args.dataset == "am":
data = AMDataset()
else:
raise ValueError(f"Unknown dataset: {args.dataset}")
hg = data[0].to(device)
num_rels = len(hg.canonical_etypes)
category = data.predict_category
labels = hg.nodes[category].data.pop("labels")
train_mask = hg.nodes[category].data.pop("train_mask")
test_mask = hg.nodes[category].data.pop("test_mask")
# Find target category and node id.
category_id = hg.ntypes.index(category)
g = dgl.to_homogeneous(hg)
node_ids = torch.arange(g.num_nodes()).to(device)
target_idx = node_ids[g.ndata[dgl.NTYPE] == category_id]
g.ndata["ntype"] = g.ndata.pop(dgl.NTYPE)
g.ndata["type_id"] = g.ndata.pop(dgl.NID)
# Find the mapping from global node IDs to type-specific node IDs.
inv_target = torch.empty((g.num_nodes(),), dtype=torch.int64).to(device)
inv_target[target_idx] = torch.arange(
0, target_idx.shape[0], dtype=inv_target.dtype
).to(device)
# Create RGCN model.
in_size = g.num_nodes() # featureless with one-hot encoding
out_size = data.num_classes
num_bases = 20
fanouts = [4, 4]
model = RGCN(in_size, 16, out_size, num_rels, num_bases).to(device)
train(
device,
g,
target_idx,
labels,
train_mask,
model,
fanouts,
)
test_idx = torch.nonzero(test_mask, as_tuple=False).squeeze()
test_sampler = MultiLayerNeighborSampler([-1, -1])
test_loader = DataLoader(
g,
target_idx[test_idx].type(g.idtype),
test_sampler,
device=device,
batch_size=32,
shuffle=False,
)
acc = evaluate(model, labels, test_loader, inv_target)
print(f"Test accuracy {acc:.4f}")