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utils.py
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utils.py
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import datetime
import errno
import os
import pickle
import random
from pprint import pprint
import dgl
import numpy as np
import torch
from dgl.data.utils import _get_dgl_url, download, get_download_dir
from scipy import io as sio, sparse
def set_random_seed(seed=0):
"""Set random seed.
Parameters
----------
seed : int
Random seed to use
"""
random.seed(seed)
np.random.seed(seed)
torch.manual_seed(seed)
if torch.cuda.is_available():
torch.cuda.manual_seed(seed)
def mkdir_p(path, log=True):
"""Create a directory for the specified path.
Parameters
----------
path : str
Path name
log : bool
Whether to print result for directory creation
"""
try:
os.makedirs(path)
if log:
print("Created directory {}".format(path))
except OSError as exc:
if exc.errno == errno.EEXIST and os.path.isdir(path) and log:
print("Directory {} already exists.".format(path))
else:
raise
def get_date_postfix():
"""Get a date based postfix for directory name.
Returns
-------
post_fix : str
"""
dt = datetime.datetime.now()
post_fix = "{}_{:02d}-{:02d}-{:02d}".format(
dt.date(), dt.hour, dt.minute, dt.second
)
return post_fix
def setup_log_dir(args, sampling=False):
"""Name and create directory for logging.
Parameters
----------
args : dict
Configuration
Returns
-------
log_dir : str
Path for logging directory
sampling : bool
Whether we are using sampling based training
"""
date_postfix = get_date_postfix()
log_dir = os.path.join(
args["log_dir"], "{}_{}".format(args["dataset"], date_postfix)
)
if sampling:
log_dir = log_dir + "_sampling"
mkdir_p(log_dir)
return log_dir
# The configuration below is from the paper.
default_configure = {
"lr": 0.005, # Learning rate
"num_heads": [8], # Number of attention heads for node-level attention
"hidden_units": 8,
"dropout": 0.6,
"weight_decay": 0.001,
"num_epochs": 200,
"patience": 100,
}
sampling_configure = {"batch_size": 20}
def setup(args):
args.update(default_configure)
set_random_seed(args["seed"])
args["dataset"] = "ACMRaw" if args["hetero"] else "ACM"
args["device"] = "cuda:0" if torch.cuda.is_available() else "cpu"
args["log_dir"] = setup_log_dir(args)
return args
def setup_for_sampling(args):
args.update(default_configure)
args.update(sampling_configure)
set_random_seed()
args["device"] = "cuda:0" if torch.cuda.is_available() else "cpu"
args["log_dir"] = setup_log_dir(args, sampling=True)
return args
def get_binary_mask(total_size, indices):
mask = torch.zeros(total_size)
mask[indices] = 1
return mask.byte()
def load_acm(remove_self_loop):
url = "dataset/ACM3025.pkl"
data_path = get_download_dir() + "/ACM3025.pkl"
download(_get_dgl_url(url), path=data_path)
with open(data_path, "rb") as f:
data = pickle.load(f)
labels, features = (
torch.from_numpy(data["label"].todense()).long(),
torch.from_numpy(data["feature"].todense()).float(),
)
num_classes = labels.shape[1]
labels = labels.nonzero()[:, 1]
if remove_self_loop:
num_nodes = data["label"].shape[0]
data["PAP"] = sparse.csr_matrix(data["PAP"] - np.eye(num_nodes))
data["PLP"] = sparse.csr_matrix(data["PLP"] - np.eye(num_nodes))
# Adjacency matrices for meta path based neighbors
# (Mufei): I verified both of them are binary adjacency matrices with self loops
author_g = dgl.from_scipy(data["PAP"])
subject_g = dgl.from_scipy(data["PLP"])
gs = [author_g, subject_g]
train_idx = torch.from_numpy(data["train_idx"]).long().squeeze(0)
val_idx = torch.from_numpy(data["val_idx"]).long().squeeze(0)
test_idx = torch.from_numpy(data["test_idx"]).long().squeeze(0)
num_nodes = author_g.num_nodes()
train_mask = get_binary_mask(num_nodes, train_idx)
val_mask = get_binary_mask(num_nodes, val_idx)
test_mask = get_binary_mask(num_nodes, test_idx)
print("dataset loaded")
pprint(
{
"dataset": "ACM",
"train": train_mask.sum().item() / num_nodes,
"val": val_mask.sum().item() / num_nodes,
"test": test_mask.sum().item() / num_nodes,
}
)
return (
gs,
features,
labels,
num_classes,
train_idx,
val_idx,
test_idx,
train_mask,
val_mask,
test_mask,
)
def load_acm_raw(remove_self_loop):
assert not remove_self_loop
url = "dataset/ACM.mat"
data_path = get_download_dir() + "/ACM.mat"
download(_get_dgl_url(url), path=data_path)
data = sio.loadmat(data_path)
p_vs_l = data["PvsL"] # paper-field?
p_vs_a = data["PvsA"] # paper-author
p_vs_t = data["PvsT"] # paper-term, bag of words
p_vs_c = data["PvsC"] # paper-conference, labels come from that
# We assign
# (1) KDD papers as class 0 (data mining),
# (2) SIGMOD and VLDB papers as class 1 (database),
# (3) SIGCOMM and MOBICOMM papers as class 2 (communication)
conf_ids = [0, 1, 9, 10, 13]
label_ids = [0, 1, 2, 2, 1]
p_vs_c_filter = p_vs_c[:, conf_ids]
p_selected = (p_vs_c_filter.sum(1) != 0).A1.nonzero()[0]
p_vs_l = p_vs_l[p_selected]
p_vs_a = p_vs_a[p_selected]
p_vs_t = p_vs_t[p_selected]
p_vs_c = p_vs_c[p_selected]
hg = dgl.heterograph(
{
("paper", "pa", "author"): p_vs_a.nonzero(),
("author", "ap", "paper"): p_vs_a.transpose().nonzero(),
("paper", "pf", "field"): p_vs_l.nonzero(),
("field", "fp", "paper"): p_vs_l.transpose().nonzero(),
}
)
features = torch.FloatTensor(p_vs_t.toarray())
pc_p, pc_c = p_vs_c.nonzero()
labels = np.zeros(len(p_selected), dtype=np.int64)
for conf_id, label_id in zip(conf_ids, label_ids):
labels[pc_p[pc_c == conf_id]] = label_id
labels = torch.LongTensor(labels)
num_classes = 3
float_mask = np.zeros(len(pc_p))
for conf_id in conf_ids:
pc_c_mask = pc_c == conf_id
float_mask[pc_c_mask] = np.random.permutation(
np.linspace(0, 1, pc_c_mask.sum())
)
train_idx = np.where(float_mask <= 0.2)[0]
val_idx = np.where((float_mask > 0.2) & (float_mask <= 0.3))[0]
test_idx = np.where(float_mask > 0.3)[0]
num_nodes = hg.num_nodes("paper")
train_mask = get_binary_mask(num_nodes, train_idx)
val_mask = get_binary_mask(num_nodes, val_idx)
test_mask = get_binary_mask(num_nodes, test_idx)
return (
hg,
features,
labels,
num_classes,
train_idx,
val_idx,
test_idx,
train_mask,
val_mask,
test_mask,
)
def load_data(dataset, remove_self_loop=False):
if dataset == "ACM":
return load_acm(remove_self_loop)
elif dataset == "ACMRaw":
return load_acm_raw(remove_self_loop)
else:
return NotImplementedError("Unsupported dataset {}".format(dataset))
class EarlyStopping(object):
def __init__(self, patience=10):
dt = datetime.datetime.now()
self.filename = "early_stop_{}_{:02d}-{:02d}-{:02d}.pth".format(
dt.date(), dt.hour, dt.minute, dt.second
)
self.patience = patience
self.counter = 0
self.best_acc = None
self.best_loss = None
self.early_stop = False
def step(self, loss, acc, model):
if self.best_loss is None:
self.best_acc = acc
self.best_loss = loss
self.save_checkpoint(model)
elif (loss > self.best_loss) and (acc < self.best_acc):
self.counter += 1
print(
f"EarlyStopping counter: {self.counter} out of {self.patience}"
)
if self.counter >= self.patience:
self.early_stop = True
else:
if (loss <= self.best_loss) and (acc >= self.best_acc):
self.save_checkpoint(model)
self.best_loss = np.min((loss, self.best_loss))
self.best_acc = np.max((acc, self.best_acc))
self.counter = 0
return self.early_stop
def save_checkpoint(self, model):
"""Saves model when validation loss decreases."""
torch.save(model.state_dict(), self.filename)
def load_checkpoint(self, model):
"""Load the latest checkpoint."""
model.load_state_dict(torch.load(self.filename))