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main_CSL_graph_classification.py
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main_CSL_graph_classification.py
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"""
IMPORTING LIBS
"""
import dgl
import numpy as np
import os
import socket
import time
import random
import glob
import argparse, json
import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim
from torch.utils.data import DataLoader
from tensorboardX import SummaryWriter
from tqdm import tqdm
class DotDict(dict):
def __init__(self, **kwds):
self.update(kwds)
self.__dict__ = self
"""
IMPORTING CUSTOM MODULES/METHODS
"""
from nets.CSL_graph_classification.load_net import gnn_model # import GNNs
from data.data import LoadData # import dataset
"""
GPU Setup
"""
def gpu_setup(use_gpu, gpu_id):
os.environ["CUDA_DEVICE_ORDER"] = "PCI_BUS_ID"
os.environ["CUDA_VISIBLE_DEVICES"] = str(gpu_id)
if torch.cuda.is_available() and use_gpu:
print('cuda available with GPU:',torch.cuda.get_device_name(0))
device = torch.device("cuda")
else:
print('cuda not available')
device = torch.device("cpu")
return device
"""
VIEWING MODEL CONFIG AND PARAMS
"""
def view_model_param(MODEL_NAME, net_params):
model = gnn_model(MODEL_NAME, net_params)
total_param = 0
print("MODEL DETAILS:\n")
#print(model)
for param in model.parameters():
# print(param.data.size())
total_param += np.prod(list(param.data.size()))
print('MODEL/Total parameters:', MODEL_NAME, total_param)
return total_param
"""
TRAINING CODE
"""
def train_val_pipeline(MODEL_NAME, DATASET_NAME, params, net_params, dirs):
avg_test_acc = []
avg_train_acc = []
avg_epochs = []
t0 = time.time()
per_epoch_time = []
dataset = LoadData(DATASET_NAME)
if MODEL_NAME in ['GCN', 'GAT']:
if net_params['self_loop']:
print("[!] Adding graph self-loops for GCN/GAT models (central node trick).")
dataset._add_self_loops()
if net_params['pos_enc']:
print("[!] Adding graph positional encoding.")
dataset._add_positional_encodings(net_params['pos_enc_dim'])
trainset, valset, testset = dataset.train, dataset.val, dataset.test
root_log_dir, root_ckpt_dir, write_file_name, write_config_file = dirs
device = net_params['device']
# Write the network and optimization hyper-parameters in folder config/
with open(write_config_file + '.txt', 'w') as f:
f.write("""Dataset: {},\nModel: {}\n\nparams={}\n\nnet_params={}\n\n\nTotal Parameters: {}\n\n""" .format(DATASET_NAME, MODEL_NAME, params, net_params, net_params['total_param']))
# At any point you can hit Ctrl + C to break out of training early.
try:
for split_number in range(5):
t0_split = time.time()
log_dir = os.path.join(root_log_dir, "RUN_" + str(split_number))
writer = SummaryWriter(log_dir=log_dir)
# setting seeds
random.seed(params['seed'])
np.random.seed(params['seed'])
torch.manual_seed(params['seed'])
if device.type == 'cuda':
torch.cuda.manual_seed(params['seed'])
print("RUN NUMBER: ", split_number)
trainset, valset, testset = dataset.train[split_number], dataset.val[split_number], dataset.test[split_number]
print("Training Graphs: ", len(trainset))
print("Validation Graphs: ", len(valset))
print("Test Graphs: ", len(testset))
print("Number of Classes: ", net_params['n_classes'])
model = gnn_model(MODEL_NAME, net_params)
model = model.to(device)
optimizer = optim.Adam(model.parameters(), lr=params['init_lr'], weight_decay=params['weight_decay'])
scheduler = optim.lr_scheduler.ReduceLROnPlateau(optimizer, mode='min',
factor=params['lr_reduce_factor'],
patience=params['lr_schedule_patience'],
verbose=True)
epoch_train_losses, epoch_val_losses = [], []
epoch_train_accs, epoch_val_accs = [], []
# batching exception for Diffpool
drop_last = True if MODEL_NAME == 'DiffPool' else False
# drop_last = False
if MODEL_NAME in ['RingGNN', '3WLGNN']:
# import train functions specific for WL-GNNs
from train.train_CSL_graph_classification import train_epoch_dense as train_epoch, evaluate_network_dense as evaluate_network
from functools import partial # util function to pass pos_enc flag to collate function
train_loader = DataLoader(trainset, shuffle=True, collate_fn=partial(dataset.collate_dense_gnn, pos_enc=net_params['pos_enc']))
val_loader = DataLoader(valset, shuffle=False, collate_fn=partial(dataset.collate_dense_gnn, pos_enc=net_params['pos_enc']))
test_loader = DataLoader(testset, shuffle=False, collate_fn=partial(dataset.collate_dense_gnn, pos_enc=net_params['pos_enc']))
else:
# import train functions for all other GCNs
from train.train_CSL_graph_classification import train_epoch_sparse as train_epoch, evaluate_network_sparse as evaluate_network
train_loader = DataLoader(trainset, batch_size=params['batch_size'], shuffle=True, drop_last=drop_last, collate_fn=dataset.collate)
val_loader = DataLoader(valset, batch_size=params['batch_size'], shuffle=False, drop_last=drop_last, collate_fn=dataset.collate)
test_loader = DataLoader(testset, batch_size=params['batch_size'], shuffle=False, drop_last=drop_last, collate_fn=dataset.collate)
with tqdm(range(params['epochs'])) as t:
for epoch in t:
t.set_description('Epoch %d' % epoch)
start = time.time()
if MODEL_NAME in ['RingGNN', '3WLGNN']: # since different batch training function for dense GNNs
epoch_train_loss, epoch_train_acc, optimizer = train_epoch(model, optimizer, device, train_loader, epoch, params['batch_size'])
else: # for all other models common train function
epoch_train_loss, epoch_train_acc, optimizer = train_epoch(model, optimizer, device, train_loader, epoch)
#epoch_train_loss, epoch_train_acc, optimizer = train_epoch(model, optimizer, device, train_loader, epoch)
epoch_val_loss, epoch_val_acc = evaluate_network(model, device, val_loader, epoch)
_, epoch_test_acc = evaluate_network(model, device, test_loader, epoch)
epoch_train_losses.append(epoch_train_loss)
epoch_val_losses.append(epoch_val_loss)
epoch_train_accs.append(epoch_train_acc)
epoch_val_accs.append(epoch_val_acc)
writer.add_scalar('train/_loss', epoch_train_loss, epoch)
writer.add_scalar('val/_loss', epoch_val_loss, epoch)
writer.add_scalar('train/_acc', epoch_train_acc, epoch)
writer.add_scalar('val/_acc', epoch_val_acc, epoch)
writer.add_scalar('test/_acc', epoch_test_acc, epoch)
writer.add_scalar('learning_rate', optimizer.param_groups[0]['lr'], epoch)
epoch_train_acc = 100.* epoch_train_acc
epoch_test_acc = 100.* epoch_test_acc
t.set_postfix(time=time.time()-start, lr=optimizer.param_groups[0]['lr'],
train_loss=epoch_train_loss, val_loss=epoch_val_loss,
train_acc=epoch_train_acc, val_acc=epoch_val_acc,
test_acc=epoch_test_acc)
per_epoch_time.append(time.time()-start)
# Saving checkpoint
ckpt_dir = os.path.join(root_ckpt_dir, "RUN_" + str(split_number))
if not os.path.exists(ckpt_dir):
os.makedirs(ckpt_dir)
torch.save(model.state_dict(), '{}.pkl'.format(ckpt_dir + "/epoch_" + str(epoch)))
files = glob.glob(ckpt_dir + '/*.pkl')
for file in files:
epoch_nb = file.split('_')[-1]
epoch_nb = int(epoch_nb.split('.')[0])
if epoch_nb < epoch-1:
os.remove(file)
scheduler.step(epoch_val_loss)
if optimizer.param_groups[0]['lr'] < params['min_lr']:
print("\n!! LR EQUAL TO MIN LR SET.")
break
# Stop training after params['max_time'] hours
if time.time()-t0_split > params['max_time']*3600/10: # Dividing max_time by 10, since there are 10 runs in TUs
print('-' * 89)
print("Max_time for one train-val-test split experiment elapsed {:.3f} hours, so stopping".format(params['max_time']/10))
break
_, test_acc = evaluate_network(model, device, test_loader, epoch)
_, train_acc = evaluate_network(model, device, train_loader, epoch)
avg_test_acc.append(test_acc)
avg_train_acc.append(train_acc)
avg_epochs.append(epoch)
print("Test Accuracy [LAST EPOCH]: {:.4f}".format(test_acc))
print("Train Accuracy [LAST EPOCH]: {:.4f}".format(train_acc))
except KeyboardInterrupt:
print('-' * 89)
print('Exiting from training early because of KeyboardInterrupt')
print("TOTAL TIME TAKEN: {:.4f}hrs".format((time.time()-t0)/3600))
print("AVG TIME PER EPOCH: {:.4f}s".format(np.mean(per_epoch_time)))
# Final test accuracy value averaged over 5-fold
print("""\n\n\nFINAL RESULTS\n\nTEST ACCURACY averaged: {:.4f} with s.d. {:.4f}""" .format(np.mean(np.array(avg_test_acc))*100, np.std(avg_test_acc)*100))
print("\nAll splits Test Accuracies:\n", avg_test_acc)
print("""\n\n\nFINAL RESULTS\n\nTRAIN ACCURACY averaged: {:.4f} with s.d. {:.4f}""" .format(np.mean(np.array(avg_train_acc))*100, np.std(avg_train_acc)*100))
print("\nAll splits Train Accuracies:\n", avg_train_acc)
writer.close()
"""
Write the results in out/results folder
"""
with open(write_file_name + '.txt', 'w') as f:
f.write("""Dataset: {},\nModel: {}\n\nparams={}\n\nnet_params={}\n\n{}\n\nTotal Parameters: {}\n\n
FINAL RESULTS\nTEST ACCURACY averaged: {:.3f}\n with test acc s.d. {:.3f}\nTRAIN ACCURACY averaged: {:.3f}\n with train s.d. {:.3f}\n\n
Convergence Time (Epochs): {:.3f}\nTotal Time Taken: {:.3f} hrs\nAverage Time Per Epoch: {:.3f} s\n\n\nAll Splits Test Accuracies: {}\n\nAll Splits Train Accuracies: {}"""\
.format(DATASET_NAME, MODEL_NAME, params, net_params, model, net_params['total_param'],
np.mean(np.array(avg_test_acc))*100, np.std(avg_test_acc)*100,
np.mean(np.array(avg_train_acc))*100, np.std(avg_train_acc)*100, np.mean(np.array(avg_epochs)),
(time.time()-t0)/3600, np.mean(per_epoch_time), avg_test_acc, avg_train_acc))
def main():
"""
USER CONTROLS
"""
parser = argparse.ArgumentParser()
parser.add_argument('--config', help="Please give a config.json file with training/model/data/param details")
parser.add_argument('--gpu_id', help="Please give a value for gpu id")
parser.add_argument('--model', help="Please give a value for model name")
parser.add_argument('--dataset', help="Please give a value for dataset name")
parser.add_argument('--out_dir', help="Please give a value for out_dir")
parser.add_argument('--seed', help="Please give a value for seed")
parser.add_argument('--epochs', help="Please give a value for epochs")
parser.add_argument('--batch_size', help="Please give a value for batch_size")
parser.add_argument('--init_lr', help="Please give a value for init_lr")
parser.add_argument('--lr_reduce_factor', help="Please give a value for lr_reduce_factor")
parser.add_argument('--lr_schedule_patience', help="Please give a value for lr_schedule_patience")
parser.add_argument('--min_lr', help="Please give a value for min_lr")
parser.add_argument('--weight_decay', help="Please give a value for weight_decay")
parser.add_argument('--print_epoch_interval', help="Please give a value for print_epoch_interval")
parser.add_argument('--L', help="Please give a value for L")
parser.add_argument('--hidden_dim', help="Please give a value for hidden_dim")
parser.add_argument('--out_dim', help="Please give a value for out_dim")
parser.add_argument('--residual', help="Please give a value for residual")
parser.add_argument('--edge_feat', help="Please give a value for edge_feat")
parser.add_argument('--readout', help="Please give a value for readout")
parser.add_argument('--kernel', help="Please give a value for kernel")
parser.add_argument('--n_heads', help="Please give a value for n_heads")
parser.add_argument('--gated', help="Please give a value for gated")
parser.add_argument('--in_feat_dropout', help="Please give a value for in_feat_dropout")
parser.add_argument('--dropout', help="Please give a value for dropout")
parser.add_argument('--graph_norm', help="Please give a value for graph_norm")
parser.add_argument('--batch_norm', help="Please give a value for batch_norm")
parser.add_argument('--sage_aggregator', help="Please give a value for sage_aggregator")
parser.add_argument('--data_mode', help="Please give a value for data_mode")
parser.add_argument('--num_pool', help="Please give a value for num_pool")
parser.add_argument('--gnn_per_block', help="Please give a value for gnn_per_block")
parser.add_argument('--embedding_dim', help="Please give a value for embedding_dim")
parser.add_argument('--pool_ratio', help="Please give a value for pool_ratio")
parser.add_argument('--linkpred', help="Please give a value for linkpred")
parser.add_argument('--cat', help="Please give a value for cat")
parser.add_argument('--self_loop', help="Please give a value for self_loop")
parser.add_argument('--max_time', help="Please give a value for max_time")
parser.add_argument('--pos_enc_dim', help="Please give a value for pos_enc_dim")
args = parser.parse_args()
with open(args.config) as f:
config = json.load(f)
# device
if args.gpu_id is not None:
config['gpu']['id'] = int(args.gpu_id)
config['gpu']['use'] = True
device = gpu_setup(config['gpu']['use'], config['gpu']['id'])
# model, dataset, out_dir
if args.model is not None:
MODEL_NAME = args.model
else:
MODEL_NAME = config['model']
if args.dataset is not None:
DATASET_NAME = args.dataset
else:
DATASET_NAME = config['dataset']
dataset = LoadData(DATASET_NAME)
if args.out_dir is not None:
out_dir = args.out_dir
else:
out_dir = config['out_dir']
# parameters
params = config['params']
if args.seed is not None:
params['seed'] = int(args.seed)
if args.epochs is not None:
params['epochs'] = int(args.epochs)
if args.batch_size is not None:
params['batch_size'] = int(args.batch_size)
if args.init_lr is not None:
params['init_lr'] = float(args.init_lr)
if args.lr_reduce_factor is not None:
params['lr_reduce_factor'] = float(args.lr_reduce_factor)
if args.lr_schedule_patience is not None:
params['lr_schedule_patience'] = int(args.lr_schedule_patience)
if args.min_lr is not None:
params['min_lr'] = float(args.min_lr)
if args.weight_decay is not None:
params['weight_decay'] = float(args.weight_decay)
if args.print_epoch_interval is not None:
params['print_epoch_interval'] = int(args.print_epoch_interval)
if args.max_time is not None:
params['max_time'] = float(args.max_time)
# network parameters
net_params = config['net_params']
net_params['device'] = device
net_params['gpu_id'] = config['gpu']['id']
net_params['batch_size'] = params['batch_size']
if args.L is not None:
net_params['L'] = int(args.L)
if args.hidden_dim is not None:
net_params['hidden_dim'] = int(args.hidden_dim)
if args.out_dim is not None:
net_params['out_dim'] = int(args.out_dim)
if args.residual is not None:
net_params['residual'] = True if args.residual=='True' else False
if args.edge_feat is not None:
net_params['edge_feat'] = True if args.edge_feat=='True' else False
if args.readout is not None:
net_params['readout'] = args.readout
if args.kernel is not None:
net_params['kernel'] = int(args.kernel)
if args.n_heads is not None:
net_params['n_heads'] = int(args.n_heads)
if args.gated is not None:
net_params['gated'] = True if args.gated=='True' else False
if args.in_feat_dropout is not None:
net_params['in_feat_dropout'] = float(args.in_feat_dropout)
if args.dropout is not None:
net_params['dropout'] = float(args.dropout)
if args.graph_norm is not None:
net_params['graph_norm'] = True if args.graph_norm=='True' else False
if args.batch_norm is not None:
net_params['batch_norm'] = True if args.batch_norm=='True' else False
if args.sage_aggregator is not None:
net_params['sage_aggregator'] = args.sage_aggregator
if args.data_mode is not None:
net_params['data_mode'] = args.data_mode
if args.num_pool is not None:
net_params['num_pool'] = int(args.num_pool)
if args.gnn_per_block is not None:
net_params['gnn_per_block'] = int(args.gnn_per_block)
if args.embedding_dim is not None:
net_params['embedding_dim'] = int(args.embedding_dim)
if args.pool_ratio is not None:
net_params['pool_ratio'] = float(args.pool_ratio)
if args.linkpred is not None:
net_params['linkpred'] = True if args.linkpred=='True' else False
if args.cat is not None:
net_params['cat'] = True if args.cat=='True' else False
if args.self_loop is not None:
net_params['self_loop'] = True if args.self_loop=='True' else False
if args.pos_enc_dim is not None:
net_params['pos_enc_dim'] = int(args.pos_enc_dim)
# CSL
net_params['num_node_type'] = dataset.all.num_node_type
net_params['num_edge_type'] = dataset.all.num_edge_type
num_classes = len(np.unique(dataset.all.graph_labels))
net_params['n_classes'] = num_classes
# RingGNN
if MODEL_NAME == 'RingGNN':
num_nodes_train = [dataset.train[0][i][0].number_of_nodes() for i in range(len(dataset.train))]
num_nodes_test = [dataset.test[0][i][0].number_of_nodes() for i in range(len(dataset.test))]
num_nodes = num_nodes_train + num_nodes_test
net_params['avg_node_num'] = int(np.ceil(np.mean(num_nodes)))
# RingGNN, 3WLGNN
if MODEL_NAME in ['RingGNN', '3WLGNN']:
if net_params['pos_enc']:
net_params['in_dim'] = net_params['pos_enc_dim']
else:
net_params['in_dim'] = 1
root_log_dir = out_dir + 'logs/' + MODEL_NAME + "_" + DATASET_NAME + "_GPU" + str(config['gpu']['id']) + "_" + time.strftime('%Hh%Mm%Ss_on_%b_%d_%Y')
root_ckpt_dir = out_dir + 'checkpoints/' + MODEL_NAME + "_" + DATASET_NAME + "_GPU" + str(config['gpu']['id']) + "_" + time.strftime('%Hh%Mm%Ss_on_%b_%d_%Y')
write_file_name = out_dir + 'results/result_' + MODEL_NAME + "_" + DATASET_NAME + "_GPU" + str(config['gpu']['id']) + "_" + time.strftime('%Hh%Mm%Ss_on_%b_%d_%Y')
write_config_file = out_dir + 'configs/config_' + MODEL_NAME + "_" + DATASET_NAME + "_GPU" + str(config['gpu']['id']) + "_" + time.strftime('%Hh%Mm%Ss_on_%b_%d_%Y')
dirs = root_log_dir, root_ckpt_dir, write_file_name, write_config_file
if not os.path.exists(out_dir + 'results'):
os.makedirs(out_dir + 'results')
if not os.path.exists(out_dir + 'configs'):
os.makedirs(out_dir + 'configs')
net_params['total_param'] = view_model_param(MODEL_NAME, net_params)
train_val_pipeline(MODEL_NAME, DATASET_NAME, params, net_params, dirs)
main()