212 lines
6.9 KiB
Python
212 lines
6.9 KiB
Python
import glob
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import os
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import dgl
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import dgl.nn.pytorch as dglnn
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import torch
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import torch.nn as nn
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import torch.nn.functional as F
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import torch.optim as optim
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import torchmetrics.functional as MF
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import tqdm
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from ogb.nodeproppred import DglNodePropPredDataset
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from pytorch_lightning import LightningDataModule, LightningModule, Trainer
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from pytorch_lightning.callbacks import ModelCheckpoint
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from torchmetrics import Accuracy
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class SAGE(LightningModule):
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def __init__(self, in_feats, n_hidden, n_classes):
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super().__init__()
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self.save_hyperparameters()
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self.layers = nn.ModuleList()
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self.layers.append(dglnn.SAGEConv(in_feats, n_hidden, "mean"))
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self.layers.append(dglnn.SAGEConv(n_hidden, n_hidden, "mean"))
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self.layers.append(dglnn.SAGEConv(n_hidden, n_classes, "mean"))
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self.dropout = nn.Dropout(0.5)
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self.n_hidden = n_hidden
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self.n_classes = n_classes
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self.train_acc = Accuracy(task="multiclass", num_classes=n_classes)
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self.val_acc = Accuracy(task="multiclass", num_classes=n_classes)
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def forward(self, blocks, x):
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h = x
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for l, (layer, block) in enumerate(zip(self.layers, blocks)):
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h = layer(block, h)
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if l != len(self.layers) - 1:
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h = F.relu(h)
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h = self.dropout(h)
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return h
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def inference(self, g, device, batch_size, num_workers, buffer_device=None):
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# The difference between this inference function and the one in the official
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# example is that the intermediate results can also benefit from prefetching.
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g.ndata["h"] = g.ndata["feat"]
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sampler = dgl.dataloading.MultiLayerFullNeighborSampler(
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1, prefetch_node_feats=["h"]
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)
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dataloader = dgl.dataloading.DataLoader(
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g,
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torch.arange(g.num_nodes()).to(g.device),
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sampler,
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device=device,
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batch_size=batch_size,
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shuffle=False,
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drop_last=False,
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num_workers=num_workers,
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persistent_workers=(num_workers > 0),
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)
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if buffer_device is None:
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buffer_device = device
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for l, layer in enumerate(self.layers):
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y = torch.zeros(
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g.num_nodes(),
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self.n_hidden if l != len(self.layers) - 1 else self.n_classes,
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device=buffer_device,
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)
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for input_nodes, output_nodes, blocks in tqdm.tqdm(dataloader):
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x = blocks[0].srcdata["h"]
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h = layer(blocks[0], x)
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if l != len(self.layers) - 1:
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h = F.relu(h)
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h = self.dropout(h)
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y[output_nodes] = h.to(buffer_device)
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g.ndata["h"] = y
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return y
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def training_step(self, batch, batch_idx):
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input_nodes, output_nodes, blocks = batch
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x = blocks[0].srcdata["feat"]
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y = blocks[-1].dstdata["label"]
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y_hat = self(blocks, x)
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loss = F.cross_entropy(y_hat, y)
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self.train_acc(torch.argmax(y_hat, 1), y)
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self.log(
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"train_acc",
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self.train_acc,
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prog_bar=True,
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on_step=True,
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on_epoch=False,
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)
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return loss
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def validation_step(self, batch, batch_idx):
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input_nodes, output_nodes, blocks = batch
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x = blocks[0].srcdata["feat"]
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y = blocks[-1].dstdata["label"]
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y_hat = self(blocks, x)
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self.val_acc(torch.argmax(y_hat, 1), y)
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self.log(
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"val_acc",
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self.val_acc,
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prog_bar=True,
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on_step=True,
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on_epoch=True,
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sync_dist=True,
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)
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def configure_optimizers(self):
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optimizer = torch.optim.Adam(
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self.parameters(), lr=0.001, weight_decay=5e-4
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)
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return optimizer
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class DataModule(LightningDataModule):
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def __init__(
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self, graph, train_idx, val_idx, fanouts, batch_size, n_classes
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):
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super().__init__()
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sampler = dgl.dataloading.NeighborSampler(
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fanouts, prefetch_node_feats=["feat"], prefetch_labels=["label"]
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)
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self.g = graph
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self.train_idx, self.val_idx = train_idx, val_idx
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self.sampler = sampler
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self.batch_size = batch_size
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self.in_feats = graph.ndata["feat"].shape[1]
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self.n_classes = n_classes
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def train_dataloader(self):
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return dgl.dataloading.DataLoader(
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self.g,
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self.train_idx.to("cuda"),
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self.sampler,
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device="cuda",
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batch_size=self.batch_size,
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shuffle=True,
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drop_last=False,
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# For CPU sampling, set num_workers to nonzero and use_uva=False
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# Set use_ddp to False for single GPU.
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num_workers=0,
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use_uva=True,
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use_ddp=True,
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)
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def val_dataloader(self):
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return dgl.dataloading.DataLoader(
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self.g,
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self.val_idx.to("cuda"),
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self.sampler,
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device="cuda",
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batch_size=self.batch_size,
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shuffle=True,
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drop_last=False,
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num_workers=0,
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use_uva=True,
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)
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if __name__ == "__main__":
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dataset = DglNodePropPredDataset("ogbn-products")
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graph, labels = dataset[0]
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graph.ndata["label"] = labels.squeeze()
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graph.create_formats_()
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split_idx = dataset.get_idx_split()
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train_idx, val_idx, test_idx = (
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split_idx["train"],
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split_idx["valid"],
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split_idx["test"],
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)
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datamodule = DataModule(
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graph, train_idx, val_idx, [15, 10, 5], 1024, dataset.num_classes
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)
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model = SAGE(datamodule.in_feats, 256, datamodule.n_classes)
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# Train
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checkpoint_callback = ModelCheckpoint(monitor="val_acc", save_top_k=1)
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# Use this for single GPU
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# trainer = Trainer(accelerator="gpu", devices=[0], max_epochs=10,
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# callbacks=[checkpoint_callback])
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trainer = Trainer(
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accelerator="gpu",
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devices=[0, 1, 2, 3],
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max_epochs=10,
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callbacks=[checkpoint_callback],
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strategy="ddp_spawn",
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)
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trainer.fit(model, datamodule=datamodule)
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# Test
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dirs = glob.glob("./lightning_logs/*")
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version = max([int(os.path.split(x)[-1].split("_")[-1]) for x in dirs])
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logdir = "./lightning_logs/version_%d" % version
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print("Evaluating model in", logdir)
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ckpt = glob.glob(os.path.join(logdir, "checkpoints", "*"))[0]
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model = SAGE.load_from_checkpoint(
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checkpoint_path=ckpt, hparams_file=os.path.join(logdir, "hparams.yaml")
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).to("cuda")
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with torch.no_grad():
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pred = model.inference(graph, "cuda", 4096, 12, graph.device)
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pred = pred[test_idx]
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label = graph.ndata["label"][test_idx]
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acc = MF.accuracy(
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pred, label, task="multiclass", num_classes=datamodule.n_classes
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)
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print("Test accuracy:", acc)
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