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appnp.py
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appnp.py
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import argparse, time
import numpy as np
import dgl
import mxnet as mx
from mxnet import nd, gluon
from mxnet.gluon import nn
import dgl
from dgl.data import register_data_args
from dgl.data import CoraGraphDataset, CiteseerGraphDataset, PubmedGraphDataset
from dgl.nn.mxnet.conv import APPNPConv
class APPNP(nn.Block):
def __init__(self,
g,
in_feats,
hiddens,
n_classes,
activation,
feat_drop,
edge_drop,
alpha,
k):
super(APPNP, self).__init__()
self.g = g
with self.name_scope():
self.layers = nn.Sequential()
# input layer
self.layers.add(nn.Dense(hiddens[0], in_units=in_feats))
# hidden layers
for i in range(1, len(hiddens)):
self.layers.add(nn.Dense(hiddens[i], in_units=hiddens[i - 1]))
# output layer
self.layers.add(nn.Dense(n_classes, in_units=hiddens[-1]))
self.activation = activation
if feat_drop:
self.feat_drop = nn.Dropout(feat_drop)
else:
self.feat_drop = lambda x: x
self.propagate = APPNPConv(k, alpha, edge_drop)
def forward(self, features):
# prediction step
h = features
h = self.feat_drop(h)
h = self.activation(self.layers[0](h))
for layer in self.layers[1:-1]:
h = self.activation(layer(h))
h = self.layers[-1](self.feat_drop(h))
# propagation step
h = self.propagate(self.g, h)
return h
def evaluate(model, features, labels, mask):
pred = model(features).argmax(axis=1)
accuracy = ((pred == labels) * mask).sum() / mask.sum().asscalar()
return accuracy.asscalar()
def main(args):
# load and preprocess dataset
if args.dataset == 'cora':
data = CoraGraphDataset()
elif args.dataset == 'citeseer':
data = CiteseerGraphDataset()
elif args.dataset == 'pubmed':
data = PubmedGraphDataset()
else:
raise ValueError('Unknown dataset: {}'.format(args.dataset))
g = data[0]
if args.gpu < 0:
cuda = False
ctx = mx.cpu(0)
else:
cuda = True
ctx = mx.gpu(args.gpu)
g = g.to(ctx)
features = g.ndata['feat']
labels = mx.nd.array(g.ndata['label'], dtype="float32", ctx=ctx)
train_mask = g.ndata['train_mask']
val_mask = g.ndata['val_mask']
test_mask = g.ndata['test_mask']
in_feats = features.shape[1]
n_classes = data.num_labels
n_edges = data.graph.number_of_edges()
print("""----Data statistics------'
#Edges %d
#Classes %d
#Train samples %d
#Val samples %d
#Test samples %d""" %
(n_edges, n_classes,
train_mask.sum().asscalar(),
val_mask.sum().asscalar(),
test_mask.sum().asscalar()))
# add self loop
g = dgl.remove_self_loop(g)
g = dgl.add_self_loop(g)
# create APPNP model
model = APPNP(g,
in_feats,
args.hidden_sizes,
n_classes,
nd.relu,
args.in_drop,
args.edge_drop,
args.alpha,
args.k)
model.initialize(ctx=ctx)
n_train_samples = train_mask.sum().asscalar()
loss_fcn = gluon.loss.SoftmaxCELoss()
# use optimizer
print(model.collect_params())
trainer = gluon.Trainer(model.collect_params(), 'adam',
{'learning_rate': args.lr, 'wd': args.weight_decay})
# initialize graph
dur = []
for epoch in range(args.n_epochs):
if epoch >= 3:
t0 = time.time()
# forward
with mx.autograd.record():
pred = model(features)
loss = loss_fcn(pred, labels, mx.nd.expand_dims(train_mask, 1))
loss = loss.sum() / n_train_samples
loss.backward()
trainer.step(batch_size=1)
if epoch >= 3:
loss.asscalar()
dur.append(time.time() - t0)
acc = evaluate(model, features, labels, val_mask)
print("Epoch {:05d} | Time(s) {:.4f} | Loss {:.4f} | Accuracy {:.4f} | "
"ETputs(KTEPS) {:.2f}". format(
epoch, np.mean(dur), loss.asscalar(), acc, n_edges / np.mean(dur) / 1000))
# test set accuracy
acc = evaluate(model, features, labels, test_mask)
print("Test accuracy {:.2%}".format(acc))
if __name__ == '__main__':
parser = argparse.ArgumentParser(description='APPNP')
register_data_args(parser)
parser.add_argument("--in-drop", type=float, default=0.5,
help="input feature dropout")
parser.add_argument("--edge-drop", type=float, default=0.5,
help="edge propagation dropout")
parser.add_argument("--gpu", type=int, default=-1,
help="gpu")
parser.add_argument("--lr", type=float, default=1e-2,
help="learning rate")
parser.add_argument("--n-epochs", type=int, default=200,
help="number of training epochs")
parser.add_argument("--hidden_sizes", type=int, nargs='+', default=[64],
help="hidden unit sizes for appnp")
parser.add_argument("--k", type=int, default=10,
help="Number of propagation steps")
parser.add_argument("--alpha", type=float, default=0.1,
help="Teleport Probability")
parser.add_argument("--weight-decay", type=float, default=5e-4,
help="Weight for L2 loss")
args = parser.parse_args()
print(args)
main(args)