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data_utils.py
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data_utils.py
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import os
import numpy as np
import paddle
import paddle.nn.functional as F
import numpy as np
from collections import defaultdict
from scipy import sparse as sp
from sklearn.metrics import roc_auc_score, f1_score
# from torch_sparse import SparseTensor
def rand_train_test_idx(label, train_prop=.5, valid_prop=.25, ignore_negative=True):
""" randomly splits label into train/valid/test splits """
if ignore_negative:
labeled_nodes = np.where(label != -1)[0]
else:
labeled_nodes = label
n = labeled_nodes.shape[0]
train_num = int(n * train_prop)
valid_num = int(n * valid_prop)
perm = np.random.permutation(n)
train_indices = perm[:train_num]
val_indices = perm[train_num:train_num + valid_num]
test_indices = perm[train_num + valid_num:]
if not ignore_negative:
return train_indices, val_indices, test_indices
train_idx = labeled_nodes[train_indices]
valid_idx = labeled_nodes[val_indices]
test_idx = labeled_nodes[test_indices]
return train_idx, valid_idx, test_idx
def even_quantile_labels(vals, nclasses, verbose=True):
""" partitions vals into nclasses by a quantile based split,
where the first class is less than the 1/nclasses quantile,
second class is less than the 2/nclasses quantile, and so on
vals is np array
returns an np array of int class labels
"""
label = -1 * np.ones(vals.shape[0], dtype=np.int)
interval_lst = []
lower = -np.inf
for k in range(nclasses - 1):
upper = np.nanquantile(vals, (k + 1) / nclasses)
interval_lst.append((lower, upper))
inds = (vals >= lower) * (vals < upper)
label[inds] = k
lower = upper
label[vals >= lower] = nclasses - 1
interval_lst.append((lower, np.inf))
if verbose:
print('Class Label Intervals:')
for class_idx, interval in enumerate(interval_lst):
print(f'Class {class_idx}: [{interval[0]}, {interval[1]})]')
return label
def to_planetoid(dataset):
"""
Takes in a NCDataset and returns the dataset in H2GCN Planetoid form, as follows:
x => the feature vectors of the training instances as scipy.sparse.csr.csr_matrix object;
tx => the feature vectors of the test instances as scipy.sparse.csr.csr_matrix object;
allx => the feature vectors of both labeled and unlabeled training instances
(a superset of ind.dataset_str.x) as scipy.sparse.csr.csr_matrix object;
y => the one-hot labels of the labeled training instances as numpy.ndarray object;
ty => the one-hot labels of the test instances as numpy.ndarray object;
ally => the labels for instances in ind.dataset_str.allx as numpy.ndarray object;
graph => a dict in the format {index: [index_of_neighbor_nodes]} as collections.defaultdict
object;
split_idx => The ogb dictionary that contains the train, valid, test splits
"""
split_idx = dataset.get_idx_split('random', 0.25)
train_idx, valid_idx, test_idx = split_idx["train"], split_idx["valid"], split_idx["test"]
graph, label = dataset[0]
label = torch.squeeze(label)
print("generate x")
x = graph['node_feat'][train_idx].numpy()
x = sp.csr_matrix(x)
tx = graph['node_feat'][test_idx].numpy()
tx = sp.csr_matrix(tx)
allx = graph['node_feat'].numpy()
allx = sp.csr_matrix(allx)
y = F.one_hot(label[train_idx]).numpy()
ty = F.one_hot(label[test_idx]).numpy()
ally = F.one_hot(label).numpy()
edge_index = graph['edge_index'].T
graph = defaultdict(list)
for i in range(0, label.shape[0]):
graph[i].append(i)
for start_edge, end_edge in edge_index:
graph[start_edge.item()].append(end_edge.item())
return x, tx, allx, y, ty, ally, graph, split_idx
def to_sparse_tensor(edge_index, edge_feat, num_nodes):
""" converts the edge_index into SparseTensor
"""
num_edges = edge_index.size(1)
(row, col), N, E = edge_index, num_nodes, num_edges
perm = (col * N + row).argsort()
row, col = row[perm], col[perm]
value = edge_feat[perm]
adj_t = SparseTensor(row=col, col=row, value=value,
sparse_sizes=(N, N), is_sorted=True)
# Pre-process some important attributes.
adj_t.storage.rowptr()
adj_t.storage.csr2csc()
return adj_t
def normalize(edge_index):
""" normalizes the edge_index
"""
adj_t = edge_index.set_diag()
deg = adj_t.sum(dim=1).to(torch.float)
deg_inv_sqrt = deg.pow(-0.5)
deg_inv_sqrt[deg_inv_sqrt == float('inf')] = 0
adj_t = deg_inv_sqrt.view(-1, 1) * adj_t * deg_inv_sqrt.view(1, -1)
return adj_t
def gen_normalized_adjs(dataset):
""" returns the normalized adjacency matrix
"""
row, col = dataset.graph['edge_index']
N = dataset.graph['num_nodes']
adj = SparseTensor(row=row, col=col, sparse_sizes=(N, N))
deg = adj.sum(dim=1).to(torch.float)
D_isqrt = deg.pow(-0.5)
D_isqrt[D_isqrt == float('inf')] = 0
DAD = D_isqrt.view(-1,1) * adj * D_isqrt.view(1,-1)
DA = D_isqrt.view(-1,1) * D_isqrt.view(-1,1) * adj
AD = adj * D_isqrt.view(1,-1) * D_isqrt.view(1,-1)
return DAD, DA, AD
def eval_acc(y_true, y_pred):
# acc_list = []
# # y_true = y_true.detach().cpu().numpy()
# y_pred = y_pred.argmax(dim=-1, keepdim=True).numpy()
# # y_pred = y_pred.argmax(dim=-1, keepdim=True).detach().cpu().numpy()
# for i in range(y_true.shape[1]):
# is_labeled = y_true[:, i] == y_true[:, i]
# correct = y_true[is_labeled, i] == y_pred[is_labeled, i]
# acc_list.append(float(np.sum(correct))/len(correct))
acc = paddle.metric.accuracy(input=y_pred, label=paddle.to_tensor(y_true), k=1)
return acc
def eval_rocauc(y_true, y_pred):
""" adapted from ogb
https://github.com/snap-stanford/ogb/blob/master/ogb/nodeproppred/evaluate.py"""
rocauc_list = []
y_true = y_true.detach().cpu().numpy()
if y_true.shape[1] == 1:
# use the predicted class for single-class classification
y_pred = F.softmax(y_pred, dim=-1)[:,1].unsqueeze(1).cpu().numpy()
else:
y_pred = y_pred.detach().cpu().numpy()
for i in range(y_true.shape[1]):
# AUC is only defined when there is at least one positive data.
if np.sum(y_true[:, i] == 1) > 0 and np.sum(y_true[:, i] == 0) > 0:
is_labeled = y_true[:, i] == y_true[:, i]
score = roc_auc_score(y_true[is_labeled, i], y_pred[is_labeled, i])
rocauc_list.append(score)
if len(rocauc_list) == 0:
raise RuntimeError(
'No positively labeled data available. Cannot compute ROC-AUC.')
return sum(rocauc_list)/len(rocauc_list)
@paddle.no_grad()
def evaluate(model, dataset, split_idx, eval_func, result=None, sampling=False, subgraph_loader=None):
if result is not None:
out = result
else:
model.eval()
if not sampling:
out = model(dataset)
else:
out = model.inference(dataset, subgraph_loader)
train_acc = eval_func(
dataset.label[split_idx['train']], out[split_idx['train']])
valid_acc = eval_func(
dataset.label[split_idx['valid']], out[split_idx['valid']])
test_acc = eval_func(
dataset.label[split_idx['test']], out[split_idx['test']])
print(train_acc)
return train_acc.item(), valid_acc.item(), test_acc.item()#, out.item()
def load_fixed_splits(dataset, sub_dataset):
""" loads saved fixed splits for dataset
"""
name = dataset
if sub_dataset and sub_dataset != 'None':
name += f'-{sub_dataset}'
if not os.path.exists(f'./data/splits/{name}-splits.npy'):
assert dataset in splits_drive_url.keys()
gdown.download(
id=splits_drive_url[dataset], \
output=f'./data/splits/{name}-splits.npy', quiet=False)
splits_lst = np.load(f'./data/splits/{name}-splits.npy', allow_pickle=True)
for i in range(len(splits_lst)):
for key in splits_lst[i]:
if not torch.is_tensor(splits_lst[i][key]):
splits_lst[i][key] = torch.as_tensor(splits_lst[i][key])
return splits_lst
dataset_drive_url = {
'twitch-gamer_feat' : '1fA9VIIEI8N0L27MSQfcBzJgRQLvSbrvR',
'twitch-gamer_edges' : '1XLETC6dG3lVl7kDmytEJ52hvDMVdxnZ0',
'snap-patents' : '1ldh23TSY1PwXia6dU0MYcpyEgX-w3Hia',
'pokec' : '1dNs5E7BrWJbgcHeQ_zuy5Ozp2tRCWG0y',
'yelp-chi': '1fAXtTVQS4CfEk4asqrFw9EPmlUPGbGtJ',
'wiki_views': '1p5DlVHrnFgYm3VsNIzahSsvCD424AyvP', # Wiki 1.9M
'wiki_edges': '14X7FlkjrlUgmnsYtPwdh-gGuFla4yb5u', # Wiki 1.9M
'wiki_features': '1ySNspxbK-snNoAZM7oxiWGvOnTRdSyEK' # Wiki 1.9M
}
splits_drive_url = {
'snap-patents' : '12xbBRqd8mtG_XkNLH8dRRNZJvVM4Pw-N',
'pokec' : '1ZhpAiyTNc0cE_hhgyiqxnkKREHK7MK-_',
}