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main.py
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main.py
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""" The main file to train a MixHop model using a full graph """
import argparse
import copy
import random
import dgl
import dgl.function as fn
import numpy as np
import torch
import torch.nn as nn
import torch.optim as optim
from dgl.data import CiteseerGraphDataset, CoraGraphDataset, PubmedGraphDataset
from tqdm import trange
class MixHopConv(nn.Module):
r"""
Description
-----------
MixHop Graph Convolutional layer from paper `MixHop: Higher-Order Graph Convolutional Architecturesvia Sparsified Neighborhood Mixing
<https://arxiv.org/pdf/1905.00067.pdf>`__.
.. math::
H^{(i+1)} =\underset{j \in P}{\Bigg\Vert} \sigma\left(\widehat{A}^j H^{(i)} W_j^{(i)}\right),
where :math:`\widehat{A}` denotes the symmetrically normalized adjacencymatrix with self-connections,
:math:`D_{ii} = \sum_{j=0} \widehat{A}_{ij}` its diagonal degree matrix,
:math:`W_j^{(i)}` denotes the trainable weight matrix of different MixHop layers.
Parameters
----------
in_dim : int
Input feature size. i.e, the number of dimensions of :math:`H^{(i)}`.
out_dim : int
Output feature size for each power.
p: list
List of powers of adjacency matrix. Defaults: ``[0, 1, 2]``.
dropout: float, optional
Dropout rate on node features. Defaults: ``0``.
activation: callable activation function/layer or None, optional
If not None, applies an activation function to the updated node features.
Default: ``None``.
batchnorm: bool, optional
If True, use batch normalization. Defaults: ``False``.
"""
def __init__(
self,
in_dim,
out_dim,
p=[0, 1, 2],
dropout=0,
activation=None,
batchnorm=False,
):
super(MixHopConv, self).__init__()
self.in_dim = in_dim
self.out_dim = out_dim
self.p = p
self.activation = activation
self.batchnorm = batchnorm
# define dropout layer
self.dropout = nn.Dropout(dropout)
# define batch norm layer
if self.batchnorm:
self.bn = nn.BatchNorm1d(out_dim * len(p))
# define weight dict for each power j
self.weights = nn.ModuleDict(
{str(j): nn.Linear(in_dim, out_dim, bias=False) for j in p}
)
def forward(self, graph, feats):
with graph.local_scope():
# assume that the graphs are undirected and graph.in_degrees() is the same as graph.out_degrees()
degs = graph.in_degrees().float().clamp(min=1)
norm = torch.pow(degs, -0.5).to(feats.device).unsqueeze(1)
max_j = max(self.p) + 1
outputs = []
for j in range(max_j):
if j in self.p:
output = self.weights[str(j)](feats)
outputs.append(output)
feats = feats * norm
graph.ndata["h"] = feats
graph.update_all(fn.copy_u("h", "m"), fn.sum("m", "h"))
feats = graph.ndata.pop("h")
feats = feats * norm
final = torch.cat(outputs, dim=1)
if self.batchnorm:
final = self.bn(final)
if self.activation is not None:
final = self.activation(final)
final = self.dropout(final)
return final
class MixHop(nn.Module):
def __init__(
self,
in_dim,
hid_dim,
out_dim,
num_layers=2,
p=[0, 1, 2],
input_dropout=0.0,
layer_dropout=0.0,
activation=None,
batchnorm=False,
):
super(MixHop, self).__init__()
self.in_dim = in_dim
self.hid_dim = hid_dim
self.out_dim = out_dim
self.num_layers = num_layers
self.p = p
self.input_dropout = input_dropout
self.layer_dropout = layer_dropout
self.activation = activation
self.batchnorm = batchnorm
self.layers = nn.ModuleList()
self.dropout = nn.Dropout(self.input_dropout)
# Input layer
self.layers.append(
MixHopConv(
self.in_dim,
self.hid_dim,
p=self.p,
dropout=self.input_dropout,
activation=self.activation,
batchnorm=self.batchnorm,
)
)
# Hidden layers with n - 1 MixHopConv layers
for i in range(self.num_layers - 2):
self.layers.append(
MixHopConv(
self.hid_dim * len(args.p),
self.hid_dim,
p=self.p,
dropout=self.layer_dropout,
activation=self.activation,
batchnorm=self.batchnorm,
)
)
self.fc_layers = nn.Linear(
self.hid_dim * len(args.p), self.out_dim, bias=False
)
def forward(self, graph, feats):
feats = self.dropout(feats)
for layer in self.layers:
feats = layer(graph, feats)
feats = self.fc_layers(feats)
return feats
def main(args):
# Step 1: Prepare graph data and retrieve train/validation/test index ============================= #
# Load from DGL dataset
if args.dataset == "Cora":
dataset = CoraGraphDataset()
elif args.dataset == "Citeseer":
dataset = CiteseerGraphDataset()
elif args.dataset == "Pubmed":
dataset = PubmedGraphDataset()
else:
raise ValueError("Dataset {} is invalid.".format(args.dataset))
graph = dataset[0]
graph = dgl.add_self_loop(graph)
# check cuda
if args.gpu >= 0 and torch.cuda.is_available():
device = "cuda:{}".format(args.gpu)
else:
device = "cpu"
# retrieve the number of classes
n_classes = dataset.num_classes
# retrieve labels of ground truth
labels = graph.ndata.pop("label").to(device).long()
# Extract node features
feats = graph.ndata.pop("feat").to(device)
n_features = feats.shape[-1]
# retrieve masks for train/validation/test
train_mask = graph.ndata.pop("train_mask")
val_mask = graph.ndata.pop("val_mask")
test_mask = graph.ndata.pop("test_mask")
train_idx = torch.nonzero(train_mask, as_tuple=False).squeeze().to(device)
val_idx = torch.nonzero(val_mask, as_tuple=False).squeeze().to(device)
test_idx = torch.nonzero(test_mask, as_tuple=False).squeeze().to(device)
graph = graph.to(device)
# Step 2: Create model =================================================================== #
model = MixHop(
in_dim=n_features,
hid_dim=args.hid_dim,
out_dim=n_classes,
num_layers=args.num_layers,
p=args.p,
input_dropout=args.input_dropout,
layer_dropout=args.layer_dropout,
activation=torch.tanh,
batchnorm=True,
)
model = model.to(device)
best_model = copy.deepcopy(model)
# Step 3: Create training components ===================================================== #
loss_fn = nn.CrossEntropyLoss()
opt = optim.SGD(model.parameters(), lr=args.lr, weight_decay=args.lamb)
scheduler = optim.lr_scheduler.StepLR(opt, args.step_size, gamma=args.gamma)
# Step 4: training epoches =============================================================== #
acc = 0
no_improvement = 0
epochs = trange(args.epochs, desc="Accuracy & Loss")
for _ in epochs:
# Training using a full graph
model.train()
logits = model(graph, feats)
# compute loss
train_loss = loss_fn(logits[train_idx], labels[train_idx])
train_acc = torch.sum(
logits[train_idx].argmax(dim=1) == labels[train_idx]
).item() / len(train_idx)
# backward
opt.zero_grad()
train_loss.backward()
opt.step()
# Validation using a full graph
model.eval()
with torch.no_grad():
valid_loss = loss_fn(logits[val_idx], labels[val_idx])
valid_acc = torch.sum(
logits[val_idx].argmax(dim=1) == labels[val_idx]
).item() / len(val_idx)
# Print out performance
epochs.set_description(
"Train Acc {:.4f} | Train Loss {:.4f} | Val Acc {:.4f} | Val loss {:.4f}".format(
train_acc, train_loss.item(), valid_acc, valid_loss.item()
)
)
if valid_acc < acc:
no_improvement += 1
if no_improvement == args.early_stopping:
print("Early stop.")
break
else:
no_improvement = 0
acc = valid_acc
best_model = copy.deepcopy(model)
scheduler.step()
best_model.eval()
logits = best_model(graph, feats)
test_acc = torch.sum(
logits[test_idx].argmax(dim=1) == labels[test_idx]
).item() / len(test_idx)
print("Test Acc {:.4f}".format(test_acc))
return test_acc
if __name__ == "__main__":
"""
MixHop Model Hyperparameters
"""
parser = argparse.ArgumentParser(description="MixHop GCN")
# data source params
parser.add_argument(
"--dataset", type=str, default="Cora", help="Name of dataset."
)
# cuda params
parser.add_argument(
"--gpu", type=int, default=-1, help="GPU index. Default: -1, using CPU."
)
# training params
parser.add_argument(
"--epochs", type=int, default=2000, help="Training epochs."
)
parser.add_argument(
"--early-stopping",
type=int,
default=200,
help="Patient epochs to wait before early stopping.",
)
parser.add_argument("--lr", type=float, default=0.5, help="Learning rate.")
parser.add_argument("--lamb", type=float, default=5e-4, help="L2 reg.")
parser.add_argument(
"--step-size",
type=int,
default=40,
help="Period of learning rate decay.",
)
parser.add_argument(
"--gamma",
type=float,
default=0.01,
help="Multiplicative factor of learning rate decay.",
)
# model params
parser.add_argument(
"--hid-dim", type=int, default=60, help="Hidden layer dimensionalities."
)
parser.add_argument(
"--num-layers", type=int, default=4, help="Number of GNN layers."
)
parser.add_argument(
"--input-dropout",
type=float,
default=0.7,
help="Dropout applied at input layer.",
)
parser.add_argument(
"--layer-dropout",
type=float,
default=0.9,
help="Dropout applied at hidden layers.",
)
parser.add_argument(
"--p", nargs="+", type=int, help="List of powers of adjacency matrix."
)
parser.set_defaults(p=[0, 1, 2])
args = parser.parse_args()
print(args)
acc_lists = []
for _ in range(100):
acc_lists.append(main(args))
acc_lists.sort()
acc_lists_top = np.array(acc_lists[50:])
mean = np.around(np.mean(acc_lists_top, axis=0), decimals=3)
std = np.around(np.std(acc_lists_top, axis=0), decimals=3)
print("Total acc: ", acc_lists)
print("Top 50 acc:", acc_lists_top)
print("mean", mean)
print("std", std)