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

214 lines
6.4 KiB
Python

import argparse
import dgl
import dgl.nn as dglnn
import torch
import torch.nn as nn
import torch.nn.functional as F
import torchmetrics.functional as MF
import tqdm
from dgl.data import AsNodePredDataset
from dgl.dataloading import (
DataLoader,
MultiLayerFullNeighborSampler,
NeighborSampler,
)
from ogb.nodeproppred import DglNodePropPredDataset
class SAGE(nn.Module):
def __init__(self, in_size, hid_size, out_size):
super().__init__()
self.layers = nn.ModuleList()
# three-layer GraphSAGE-mean
self.layers.append(dglnn.SAGEConv(in_size, hid_size, "mean"))
self.layers.append(dglnn.SAGEConv(hid_size, hid_size, "mean"))
self.layers.append(dglnn.SAGEConv(hid_size, out_size, "mean"))
self.dropout = nn.Dropout(0.5)
self.hid_size = hid_size
self.out_size = out_size
def forward(self, blocks, x):
h = x
for l, (layer, block) in enumerate(zip(self.layers, blocks)):
h = layer(block, h)
if l != len(self.layers) - 1:
h = F.relu(h)
h = self.dropout(h)
return h
def inference(self, g, device, batch_size):
"""Conduct layer-wise inference to get all the node embeddings."""
feat = g.ndata["feat"]
sampler = MultiLayerFullNeighborSampler(1, prefetch_node_feats=["feat"])
dataloader = DataLoader(
g,
torch.arange(g.num_nodes()).to(g.device),
sampler,
device=device,
batch_size=batch_size,
shuffle=False,
drop_last=False,
num_workers=0,
)
buffer_device = torch.device("cpu")
pin_memory = buffer_device != device
for l, layer in enumerate(self.layers):
y = torch.empty(
g.num_nodes(),
self.hid_size if l != len(self.layers) - 1 else self.out_size,
dtype=feat.dtype,
device=buffer_device,
pin_memory=pin_memory,
)
feat = feat.to(device)
for input_nodes, output_nodes, blocks in tqdm.tqdm(dataloader):
x = feat[input_nodes]
h = layer(blocks[0], x) # len(blocks) = 1
if l != len(self.layers) - 1:
h = F.relu(h)
h = self.dropout(h)
# by design, our output nodes are contiguous
y[output_nodes[0] : output_nodes[-1] + 1] = h.to(buffer_device)
feat = y
return y
def evaluate(model, graph, dataloader, num_classes):
model.eval()
ys = []
y_hats = []
for it, (input_nodes, output_nodes, blocks) in enumerate(dataloader):
with torch.no_grad():
x = blocks[0].srcdata["feat"]
ys.append(blocks[-1].dstdata["label"])
y_hats.append(model(blocks, x))
return MF.accuracy(
torch.cat(y_hats),
torch.cat(ys),
task="multiclass",
num_classes=num_classes,
)
def layerwise_infer(device, graph, nid, model, num_classes, batch_size):
model.eval()
with torch.no_grad():
pred = model.inference(
graph, device, batch_size
) # pred in buffer_device
pred = pred[nid]
label = graph.ndata["label"][nid].to(pred.device)
return MF.accuracy(
pred, label, task="multiclass", num_classes=num_classes
)
def train(args, device, g, dataset, model, num_classes):
# create sampler & dataloader
train_idx = dataset.train_idx.to(device)
val_idx = dataset.val_idx.to(device)
sampler = NeighborSampler(
[10, 10, 10], # fanout for [layer-0, layer-1, layer-2]
prefetch_node_feats=["feat"],
prefetch_labels=["label"],
)
use_uva = args.mode == "mixed"
train_dataloader = DataLoader(
g,
train_idx,
sampler,
device=device,
batch_size=1024,
shuffle=True,
drop_last=False,
num_workers=0,
use_uva=use_uva,
)
val_dataloader = DataLoader(
g,
val_idx,
sampler,
device=device,
batch_size=1024,
shuffle=True,
drop_last=False,
num_workers=0,
use_uva=use_uva,
)
opt = torch.optim.Adam(model.parameters(), lr=1e-3, weight_decay=5e-4)
for epoch in range(10):
model.train()
total_loss = 0
for it, (input_nodes, output_nodes, blocks) in enumerate(
train_dataloader
):
x = blocks[0].srcdata["feat"]
y = blocks[-1].dstdata["label"]
y_hat = model(blocks, x)
loss = F.cross_entropy(y_hat, y)
opt.zero_grad()
loss.backward()
opt.step()
total_loss += loss.item()
acc = evaluate(model, g, val_dataloader, num_classes)
print(
"Epoch {:05d} | Loss {:.4f} | Accuracy {:.4f} ".format(
epoch, total_loss / (it + 1), acc.item()
)
)
if __name__ == "__main__":
parser = argparse.ArgumentParser()
parser.add_argument(
"--mode",
default="mixed",
choices=["cpu", "mixed", "puregpu"],
help="Training mode. 'cpu' for CPU training, 'mixed' for CPU-GPU mixed training, "
"'puregpu' for pure-GPU training.",
)
parser.add_argument(
"--dt",
type=str,
default="float",
help="data type(float, bfloat16)",
)
args = parser.parse_args()
if not torch.cuda.is_available():
args.mode = "cpu"
print(f"Training in {args.mode} mode.")
# load and preprocess dataset
print("Loading data")
dataset = AsNodePredDataset(DglNodePropPredDataset("ogbn-products"))
g = dataset[0]
g = g.to("cuda" if args.mode == "puregpu" else "cpu")
num_classes = dataset.num_classes
device = torch.device("cpu" if args.mode == "cpu" else "cuda")
# create GraphSAGE model
in_size = g.ndata["feat"].shape[1]
out_size = dataset.num_classes
model = SAGE(in_size, 256, out_size).to(device)
# convert model and graph to bfloat16 if needed
if args.dt == "bfloat16":
g = dgl.to_bfloat16(g)
model = model.to(dtype=torch.bfloat16)
# model training
print("Training...")
train(args, device, g, dataset, model, num_classes)
# test the model
print("Testing...")
acc = layerwise_infer(
device, g, dataset.test_idx, model, num_classes, batch_size=4096
)
print("Test Accuracy {:.4f}".format(acc.item()))