def main():
start = time.time()
parser = args.parse_args()
# run some checks on arguments
check_args(parser)
# format logging
log_name = os.path.join(
parser.run_log,
'{}_run_log_{}.log'.format(parser.experiment,
dt.now().strftime("%Y%m%d_%H%M")))
log.basicConfig(filename=log_name,
format='%(asctime)s | %(name)s -- %(message)s',
level=log.INFO)
os.chmod(log_name, parser.access_mode)
# set device to CPU if available
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
print("Starting experiment {} VN -> EN NMT on {}.".format(
parser.experiment, device))
log.info("Starting experiment {} VN -> EN NMT on {}.".format(
parser.experiment, device))
# set seed for replication
random.seed(parser.seed)
np.random.seed(parser.seed)
torch.manual_seed(parser.seed)
if torch.cuda.is_available():
torch.cuda.manual_seed_all(parser.seed)
log.info("For reproducibility, the seed is set to {}.".format(parser.seed))
# set file paths
source_name = parser.source_name
target_name = parser.target_name
# get saved models dir
base_saved_models_dir = parser.save_dir
saved_models_dir = os.path.join(base_saved_models_dir,
source_name + '2' + target_name)
plots_dir = parser.plots_dir
log.info("We will save the models in this directory: {}".format(
saved_models_dir))
log.info("We will save the plots in this directory: {}".format(plots_dir))
# get data dir
main_data_path = parser.data_dir
path_to_train_data = {
'source': main_data_path + 'train.tok.' + source_name,
'target': main_data_path + 'train.tok.' + target_name
}
path_to_dev_data = {
'source': main_data_path + 'dev.tok.' + source_name,
'target': main_data_path + 'dev.tok.' + target_name
}
path_to_test_data = {
'source': main_data_path + 'test.tok.' + source_name,
'target': main_data_path + 'test.tok.' + target_name
}
# Configuration
bs = parser.batch_size
log.info("Batch size = {}.".format(bs))
enc_emb = parser.enc_emb
enc_hidden = parser.enc_hidden
enc_layers = parser.enc_layers
rnn_type = parser.rnn_type
dec_emb = parser.dec_emb
dec_hidden = parser.dec_hidden
dec_layers = parser.dec_layers
learning_rate = parser.learning_rate
num_epochs = parser.epochs
attn_flag = parser.wo_attn
log.info("The attention flag is set to {}.".format(attn_flag))
beam_size = parser.beam_size
log.info("We evaluate using beam size of {}.".format(beam_size))
train, val, test, en_lang, vi_lang = dataset_helper.train_val_load(
"", main_data_path)
# get vocab sizes
log.info('English has vocab size of: {} words.'.format(en_lang.n_words))
log.info('Vietnamese has vocab size of: {} words.'.format(vi_lang.n_words))
# get max sentence length by 95% percentile
MAX_LEN = int(train['en_len'].quantile(0.95))
log.info(
'We will have a max sentence length of {} (95 percentile).'.format(
MAX_LEN))
# set data loaders
bs_dict = {'train': bs, 'validate': 1, 'test': 1}
shuffle_dict = {'train': True, 'validate': False, 'test': False}
train_used = train
val_used = val
collate_fn_dict = {
'train': partial(dataset_helper.vocab_collate_func, MAX_LEN=MAX_LEN),
'validate': dataset_helper.vocab_collate_func_val,
'test': dataset_helper.vocab_collate_func_val
}
transformed_dataset = {
'train': dataset_helper.Vietnamese(train_used),
'validate': dataset_helper.Vietnamese(val_used, val=True),
'test': dataset_helper.Vietnamese(test, val=True)
}
dataloader = {
x: DataLoader(transformed_dataset[x],
batch_size=bs_dict[x],
collate_fn=collate_fn_dict[x],
shuffle=shuffle_dict[x],
num_workers=0)
for x in ['train', 'validate', 'test']
}
# instantiate encoder/decoder
encoder_wo_att = nnet_models.EncoderRNN(input_size=vi_lang.n_words,
embed_dim=enc_emb,
hidden_size=enc_hidden,
n_layers=enc_layers,
rnn_type=rnn_type).to(device)
decoder_wo_att = nnet_models.AttentionDecoderRNN(
output_size=en_lang.n_words,
embed_dim=dec_emb,
hidden_size=dec_hidden,
n_layers=dec_layers,
attention=attn_flag).to(device)
# instantiate optimizer
if parser.optimizer == 'sgd':
encoder_optimizer = optim.SGD(encoder_wo_att.parameters(),
lr=learning_rate,
nesterov=True,
momentum=0.99)
decoder_optimizer = optim.SGD(decoder_wo_att.parameters(),
lr=learning_rate,
nesterov=True,
momentum=0.99)
elif parser.optimizer == 'adam':
# lee kho learning rate
encoder_optimizer = optim.Adam(encoder_wo_att.parameters(), lr=1e-4)
decoder_optimizer = optim.Adam(decoder_wo_att.parameters(), lr=1e-4)
else:
raise ValueError('Invalid optimizer!')
# instantiate scheduler
enc_scheduler = ReduceLROnPlateau(encoder_optimizer,
min_lr=1e-4,
factor=0.5,
patience=0)
dec_scheduler = ReduceLROnPlateau(decoder_optimizer,
min_lr=1e-4,
factor=0.5,
patience=0)
criterion = nn.NLLLoss(ignore_index=global_variables.PAD_IDX)
log.info(
"Seq2Seq Model with the following parameters: batch_size = {}, learning_rate = {}, rnn_type = {}, enc_emb = {}, enc_hidden = {}, enc_layers = {}, dec_emb = {}, dec_hidden = {}, dec_layers = {}, num_epochs = {}, source_name = {}, target_name = {}"
.format(bs, learning_rate, rnn_type, enc_emb, enc_hidden, enc_layers,
dec_emb, dec_hidden, dec_layers, num_epochs, source_name,
target_name))
# do we want to train again?
train_again = False
encoder_save = '{}_wo_att_{}bs_{}hs_{}_{}beam_enc_{}_layer'.format(
rnn_type, bs, enc_hidden, parser.optimizer, beam_size, enc_layers)
decoder_save = '{}_wo_att_{}bs_{}hs_{}_{}beam_dec_{}_layer'.format(
rnn_type, bs, enc_hidden, parser.optimizer, beam_size, dec_layers)
if os.path.exists(utils.get_full_filepath(
saved_models_dir, encoder_save)) and os.path.exists(
utils.get_full_filepath(saved_models_dir,
decoder_save)) and (not train_again):
log.info("Retrieving saved encoder from {}".format(
utils.get_full_filepath(saved_models_dir, encoder_save)))
log.info("Retrieving saved decoder from {}".format(
utils.get_full_filepath(saved_models_dir, decoder_save)))
encoder_wo_att.load_state_dict(
torch.load(utils.get_full_filepath(saved_models_dir,
encoder_save)))
decoder_wo_att.load_state_dict(
torch.load(utils.get_full_filepath(saved_models_dir,
decoder_save)))
else:
log.info("Check if encoder path exists: {}".format(
utils.get_full_filepath(saved_models_dir, encoder_save)))
log.info("Check if decoder path exists: {}".format(
utils.get_full_filepath(saved_models_dir, decoder_save)))
log.info("Encoder and Decoder do not exist! Starting to train...")
encoder_wo_att, decoder_wo_att, loss_hist, acc_hist = train_utilities.train_model(
encoder_optimizer,
decoder_optimizer,
encoder_wo_att,
decoder_wo_att,
criterion,
"no_attention",
dataloader,
en_lang,
vi_lang,
saved_models_dir,
encoder_save,
decoder_save,
num_epochs=num_epochs,
rm=0.95,
enc_scheduler=enc_scheduler,
dec_scheduler=dec_scheduler)
log.info("Total time is: {} min : {} s".format(
(time.time() - start) // 60, (time.time() - start) % 60))
log.info(
"We will save the encoder/decoder in this directory: {}".format(
saved_models_dir))
# BLEU with beam size
bleu_no_unk, att_score_wo, pred_wo, src_wo = train_utilities.validation_beam_search(
encoder_wo_att,
decoder_wo_att,
dataloader['validate'],
en_lang,
vi_lang,
'no_attention',
beam_size,
verbose=False)
log.info("Bleu-{} Score (No UNK): {}".format(beam_size, bleu_no_unk))
print("Bleu-{} Score (No UNK): {}".format(beam_size, bleu_no_unk))
bleu_unk, att_score_wo, pred_wo, src_wo = train_utilities.validation_beam_search(
encoder_wo_att,
decoder_wo_att,
dataloader['validate'],
en_lang,
vi_lang,
'no_attention',
beam_size,
verbose=False,
replace_unk=True)
log.info("Bleu-{} Score (UNK): {}".format(beam_size, bleu_unk))
print("Bleu-{} Score (UNK): {}".format(beam_size, bleu_unk))
# generate 5 random predictions
indexes = range(len(pred_wo))
for i in np.random.choice(indexes, 5):
print('Source: {} \nPrediction: {}\n---'.format(src_wo[i], pred_wo[i]))
log.info('Source: {} \nPrediction: {}\n---'.format(
src_wo[i], pred_wo[i]))
log.info("Exported Binned Bleu Score Plot to {}!".format(plots_dir))
_, _, fig = utils.get_binned_bl_score(
encoder=encoder_wo_att,
decoder=decoder_wo_att,
val_dataset=transformed_dataset['validate'],
attn_flag=attn_flag,
beam_size=beam_size,
location=plots_dir,
collate=collate_fn_dict['validate'],
lang_en=en_lang,
lang_vi=vi_lang)
def main():
start = time.time()
parser = args.parse_args()
# run some checks on arguments
check_args(parser)
# format logging
log_name = os.path.join(
parser.run_log,
'{}_run_log_{}.log'.format(parser.experiment,
dt.now().strftime("%Y%m%d_%H%M")))
log.basicConfig(filename=log_name,
format='%(asctime)s | %(name)s -- %(message)s',
level=log.INFO)
os.chmod(log_name, parser.access_mode)
# set devise to CPU if available
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
log.info("Starting experiment {} VN -> EN NMT on {}.".format(
parser.experiment, device))
# set seed for replication
random.seed(parser.seed)
np.random.seed(parser.seed)
torch.manual_seed(parser.seed)
if torch.cuda.is_available():
torch.cuda.manual_seed_all(parser.seed)
log.info("For reproducibility, the seed is set to {}.".format(parser.seed))
# set file paths
source_name = parser.source_name
target_name = parser.target_name
# get saved models dir
base_saved_models_dir = parser.save_dir
saved_models_dir = os.path.join(base_saved_models_dir,
source_name + '2' + target_name)
plots_dir = parser.plots_dir
log.info("We will save the models in this directory: {}".format(
saved_models_dir))
log.info("We will save the plots in this directory: {}".format(plots_dir))
# get data dir
main_data_path = parser.data_dir
path_to_train_data = {
'source': main_data_path + 'train.' + source_name,
'target': main_data_path + 'train.' + target_name
}
path_to_dev_data = {
'source': main_data_path + 'dev.' + source_name,
'target': main_data_path + 'dev.' + target_name
}
# get language objects
saved_language_model_dir = os.path.join(saved_models_dir, 'lang_obj')
# get dictionary of datasets
dataset_dict = {
'train':
nmt_dataset.LanguagePair(source_name=source_name,
target_name=target_name,
filepath=path_to_train_data,
lang_obj_path=saved_language_model_dir,
minimum_count=1),
'dev':
nmt_dataset.LanguagePair(source_name=source_name,
target_name=target_name,
filepath=path_to_dev_data,
lang_obj_path=saved_language_model_dir,
minimum_count=1)
}
# get max sentence length by 99% percentile
MAX_LEN = int(dataset_dict['train'].main_df['source_len'].quantile(0.9999))
log.info("MAX_LEN (99th Percentile) = {}".format(MAX_LEN))
batchSize = parser.batch_size
log.info("Batch size = {}.".format(batchSize))
dataloader_dict = {
'train':
DataLoader(dataset_dict['train'],
batch_size=batchSize,
collate_fn=partial(nmt_dataset.vocab_collate_func,
MAX_LEN=MAX_LEN),
shuffle=True,
num_workers=0),
'dev':
DataLoader(dataset_dict['dev'],
batch_size=batchSize,
collate_fn=partial(nmt_dataset.vocab_collate_func,
MAX_LEN=MAX_LEN),
shuffle=True,
num_workers=0)
}
# Configuration
source_lang_obj = dataset_dict['train'].source_lang_obj
target_lang_obj = dataset_dict['train'].target_lang_obj
source_vocab = dataset_dict['train'].source_lang_obj.n_words
target_vocab = dataset_dict['train'].target_lang_obj.n_words
hidden_size = parser.hidden_size
rnn_layers = parser.rnn_layers
lr = parser.learning_rate
longest_label = parser.longest_label
gradient_clip = parser.gradient_clip
num_epochs = parser.epochs
log.info(
"The source vocab ({}) has {} words and target vocab ({}) has {} words"
.format(source_name, source_vocab, target_name, target_vocab))
# encoder model
encoder_rnn = nnet_models_new.EncoderRNN(input_size=source_vocab,
hidden_size=hidden_size,
numlayers=rnn_layers)
# decoder model
decoder_rnn = nnet_models_new.DecoderRNN(output_size=target_vocab,
hidden_size=hidden_size,
numlayers=rnn_layers)
# seq2seq model
nmt_rnn = nnet_models_new.seq2seq(
encoder_rnn,
decoder_rnn,
lr=lr,
hiddensize=hidden_size,
numlayers=hidden_size,
target_lang=dataset_dict['train'].target_lang_obj,
longest_label=longest_label,
clip=gradient_clip,
device=device)
log.info(
"Seq2Seq Model with the following parameters: batch_size = {}, learning_rate = {}, hidden_size = {}, rnn_layers = {}, lr = {}, longest_label = {}, gradient_clip = {}, num_epochs = {}, source_name = {}, target_name = {}"
.format(batchSize, lr, hidden_size, rnn_layers, lr, longest_label,
gradient_clip, num_epochs, source_name, target_name))
# do we want to train again?
train_again = False
saved_file_name = 'no_attn_bs{}_lr{}_hs_{}_rnnlayer{}'.format(
batchSize, lr, hidden_size, rnn_layers)
# check if there is a saved model and if we want to train again
if os.path.exists(utils.get_full_filepath(saved_models_dir,
'rnn')) and (not train_again):
log.info("Retrieving saved model from {}".format(
utils.get_full_filepath(saved_models_dir, 'rnn')))
nmt_rnn = torch.load(utils.get_full_filepath(saved_models_dir, 'rnn'),
map_location=global_variables.device)
# train model again
else:
log.info("Check if this path exists: {}".format(
utils.get_full_filepath(saved_models_dir, saved_file_name)))
log.info("It does not exist! Starting to train...")
utils.train_model(dataloader_dict,
nmt_rnn,
num_epochs=num_epochs,
saved_model_path=saved_models_dir,
enc_type=saved_file_name)
log.info("Total time is: {} min : {} s".format((time.time() - start) // 60,
(time.time() - start) % 60))
log.info("We will save the models in this directory: {}".format(
saved_models_dir))
# generate translations
use_cuda = True
utils.get_translation(nmt_rnn, 'I love to watch science movies on Mondays',
source_lang_obj, use_cuda, source_name, target_name)
utils.get_translation(nmt_rnn,
'I want to be the best friend that I can be',
source_lang_obj, use_cuda, source_name, target_name)
utils.get_translation(nmt_rnn, 'I love you', source_lang_obj, use_cuda,
source_name, target_name)
utils.get_translation(
nmt_rnn,
'I love football, I like to watch it with my friends. It is always a great time.',
source_lang_obj, use_cuda, source_name, target_name)
utils.get_translation(
nmt_rnn,
'I do not know what I would do without pizza, it is very tasty to eat. If I could have any food in the world it would probably be pizza.',
source_lang_obj, use_cuda, source_name, target_name)
utils.get_translation(
nmt_rnn,
'Trump is the worst president in all of history. He can be a real racist and say very nasty things to people of color.',
source_lang_obj, use_cuda, source_name, target_name)
utils.get_translation(nmt_rnn, 'Thank you very much.', source_lang_obj,
use_cuda, source_name, target_name)
utils.get_translation(nmt_rnn, 'Think about your own choices.',
source_lang_obj, use_cuda, source_name, target_name)
utils.get_translation(
nmt_rnn,
'I recently did a survey with over 2,000 Americans , and the average number of choices that the typical American reports making is about 70 in a typical day .',
source_lang_obj, use_cuda, source_name, target_name)
# export plot
log.info("Exported Binned Bleu Score Plot to {}!".format(plots_dir))
_, _, fig = utils.get_binned_bl_score(nmt_rnn,
dataset_dict['dev'],
plots_dir,
batchSize=batchSize)
def main():
# parse arguments
parser = args.parse_args()
# set up logger
log_path = os.path.join(parser.save_dir, "logs")
if not os.path.exists(log_path):
os.mkdir(log_path)
log_fname = os.path.join(
log_path, "{}_log_{}.log".format(parser.exp_name,
dt.now().strftime("%Y%m%d_%H%M")))
log.basicConfig(filename=log_fname,
format='%(asctime)s: %(name)s || %(message)s',
level=log.INFO)
# =============================================================================
# start
# =============================================================================
log.info("=" * 40 + " Start Program " + "=" * 40)
# =============================================================================
# misc stuff
# =============================================================================
# Set devise to CPU if available
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
log.info("Device is {}".format(device))
# set random seeds
random.seed(parser.seed)
np.random.seed(parser.seed)
torch.manual_seed(parser.seed)
if torch.cuda.is_available():
torch.cuda.manual_seed_all(parser.seed)
# set data directory
log.info("Data Directory is {}.".format(parser.data_dir))
# =============================================================================
# import data
# =============================================================================
task_names = parser.data_name.split(',')
content_headers = parser.content.split(',')
tokenizer = transformers.AutoTokenizer.from_pretrained(
parser.model, do_lower_case=parser.do_lower_case)
data_handler = myio.IO(
data_dir=parser.data_dir,
model_name=parser.model,
task_names=task_names,
tokenizer=tokenizer,
max_length=parser.input_length,
content=content_headers,
review_key=parser.review_key,
label_name=parser.label_name,
val_split=parser.val_split,
test_split=parser.test_split,
batch_size=parser.batch_size,
shuffle=not parser.no_shuffle,
cache=not parser.no_cache,
)
data_handler.read_task()
# =============================================================================
# define model
# =============================================================================
log.info("=" * 40 + " Defining Model " + "=" * 40)
config = transformers.AutoConfig.from_pretrained(parser.model)
classifier = model.Model(
model=parser.model,
config=config,
n_others=parser.n_others,
n_hidden=parser.n_class_hidden,
n_flag=parser.n_labels,
load=parser.preload_emb,
load_name=parser.preload_emb_name,
)
# =============================================================================
# define trainer
# =============================================================================
log.info("Save Directory is {}.".format(parser.save_dir))
log.info("=" * 40 + " Defining Trainer " + "=" * 40)
# create trainer object
trainer = learner.Learner(
model=classifier,
device=device,
myio=data_handler,
max_epochs=parser.max_epochs,
save_path=parser.save_dir,
lr=parser.lr,
weight_decay=parser.weight_decay,
pct_start=parser.pct_start,
anneal_strategy=parser.anneal_strategy,
cycle_momentum=parser.cycle_momentum,
log_int=parser.log_int,
buffer_break=not parser.no_early_stop,
break_int=parser.patience,
accumulate_int=parser.grad_accum,
max_grad_norm=parser.max_grad_norm,
n_others=parser.n_others,
batch_size=parser.batch_size,
check_int=parser.check_int,
save=parser.save,
test=parser.test,
)
# train model
best = trainer.learn(
model_name=parser.model,
task_name=task_names[0],
early_check=parser.early_check,
debug=parser.debug,
)
best['experiment'] = parser.exp_name
#write results to "results.jsonl"
if not os.path.exists(parser.save_dir):
os.mkdir(parser.save_dir)
results_name = os.path.join(parser.save_dir, "results.jsonl")
with open(results_name, 'a') as f:
f.write(json.dumps(best) + "\n")
log.info("=" * 40 + " Program Complete " + "=" * 40)
log.info("=" * 40 + " Results written to {} ".format(results_name) +
"=" * 40)
def main():
"""
Main method for meta-learning
"""
start = time.time()
repository = os.path.dirname(os.path.dirname(os.path.abspath(__file__)))
parser = args.parse_args()
# run some checks on arguments
check_args(parser)
# format logging
log_name = os.path.join(
parser.run_log,
'{}_meta_run_log_{}.log'.format(parser.experiment,
dt.now().strftime("%Y%m%d_%H%M")))
log.basicConfig(filename=log_name,
format='%(asctime)s | %(name)s -- %(message)s',
level=log.INFO)
os.chmod(log_name, parser.access_mode)
# set devise to CPU if available
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
log.info("Device is {}".format(device))
# set seed for replication
random.seed(parser.seed)
np.random.seed(parser.seed)
torch.manual_seed(parser.seed)
if torch.cuda.is_available():
torch.cuda.manual_seed_all(parser.seed)
log.info("Starting experiment {} meta learning on {} with model {}".format(
parser.experiment, device, parser.model))
# set tokenizer and config from Huggingface
tokenizer = transformers.AutoTokenizer.from_pretrained(
parser.model, do_lower_case=parser.do_lower_case)
config = transformers.AutoConfig.from_pretrained(parser.model)
# create IO object and import data
cache_head = os.path.join(parser.save_dir, 'cached_data')
cache_dir = os.path.join(cache_head, parser.model)
if not os.path.exists(cache_head):
os.mkdir(cache_head)
if not os.path.exists(cache_dir):
os.mkdir(cache_dir)
data_handler = myio.IO(parser.data_dir,
cache_dir,
tokenizer,
parser.max_seq_length,
parser.doc_stride,
parser.max_query_length,
batch_size=parser.batch_size,
shuffle=True,
cache=True)
# set oml
oml = meta_learner.MetaLearningClassification(
update_lr=parser.meta_update_lr,
meta_lr=parser.meta_meta_lr,
hf_model_name=parser.model,
config=config,
myio=data_handler,
max_grad_norm=parser.max_grad_norm,
device=device)
if isinstance(oml.net, nn.DataParallel):
rln = oml.net.module.model.bert
else:
rln = oml.net.model.bert
old_weights = copy.deepcopy(rln)
# freeze_layers
oml.freeze_rln()
# do meta_learning
meta_tasks = parser.meta_tasks.split(',')
# create save path
meta_RLN_head = os.path.join(parser.save_dir, "meta_weights")
if not os.path.exists(meta_RLN_head):
os.mkdir(meta_RLN_head)
meta_RLN_weights = os.path.join(meta_RLN_head,
parser.experiment + "_meta_weights.pt")
meta_steps = trange(0,
parser.meta_steps,
desc='Meta Outer',
mininterval=30)
running_loss = 0
for step in meta_steps:
# sample tasks
sample_tasks = np.random.choice(meta_tasks,
parser.n_meta_tasks,
replace=False)
# sample trajectory
d_traj = []
d_rand = []
for task in sample_tasks:
task_traj, task_rand = data_handler.sample_dl(
task=task, samples=parser.n_meta_task_samples, use='train')
d_traj += task_traj
d_rand += task_rand
loss = oml(d_traj, d_rand)
running_loss += loss
if step % parser.verbose_steps == 0:
log.info(
f"OML Loss is {loss} | Step {step} | Average is {running_loss/max(1,step)}"
)
# check if rln weights are changing
changed = False
if isinstance(oml.net, nn.DataParallel):
rln = oml.net.module.model.bert
else:
rln = oml.net.model.bert
for old, new in zip(old_weights.parameters(), rln.parameters()):
if not old.equal(new):
changed = True
break
assert changed, "Weights are the same"
# save every meta step
# for multi-GPU
if isinstance(oml.net, nn.DataParallel):
weights = oml.net.module.model.bert.state_dict()
else:
weights = oml.net.model.bert.state_dict()
torch.save(weights, meta_RLN_weights)
log.info(
f"Meta loss is {loss} | Step {step} | Average is {running_loss/(step+1)}"
)
log.info(f"Changed weights: {changed}")
log.info("Saved meta weights at {}".format(meta_RLN_weights))
log.info("Total time is: {} min : {} s".format((time.time() - start) // 60,
(time.time() - start) % 60))
from args import args
args = args.parse_args()
PERCEPTION_RATINGS = {
0: 'To Be Decided',
1: 'Major Star',
2: 'Star',
3: 'Well Known',
4: 'Recognisable',
5: 'Unimportant'}
def get_momentum_text(rating):
if rating > 500:
return 'White Hot'
elif rating > 400:
return 'Red Hot'
elif rating > 300:
return 'Very Hot'
elif rating > 200:
return 'Hot'
elif rating > 100:
return 'Very Warm'
elif rating > 0:
return 'Warm'
elif rating == 0:
return 'Neutral'
elif rating < -300:
return 'Very Cold'
def main():
start = time.time()
parser = args.parse_args()
# run some checks on arguments
check_args(parser)
# format logging
log_name = os.path.join(
parser.run_log,
'{}_run_log_{}.log'.format(parser.experiment,
dt.now().strftime("%Y%m%d_%H%M")))
log.basicConfig(filename=log_name,
format='%(asctime)s | %(name)s -- %(message)s',
level=log.INFO)
os.chmod(log_name, parser.access_mode)
# set devise to CPU if available
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
log.info("Starting experiment {} VN -> EN NMT on {}.".format(
parser.experiment, device))
# set seed for replication
random.seed(parser.seed)
np.random.seed(parser.seed)
torch.manual_seed(parser.seed)
if torch.cuda.is_available():
torch.cuda.manual_seed_all(parser.seed)
log.info("For reproducibility, the seed is set to {}.".format(parser.seed))
# set file paths
source_name = parser.source_name
target_name = parser.target_name
# get saved models dir
base_saved_models_dir = parser.save_dir
saved_models_dir = os.path.join(base_saved_models_dir,
source_name + '2' + target_name)
log.info("We will save the models in this directory: {}".format(
saved_models_dir))
# get data dir
main_data_path = parser.data_dir
path_to_train_data = {
'source': main_data_path + 'train.' + source_name,
'target': main_data_path + 'train.' + target_name
}
path_to_dev_data = {
'source': main_data_path + 'dev.' + source_name,
'target': main_data_path + 'dev.' + target_name
}
# get language objects
saved_language_model_dir = os.path.join(saved_models_dir, 'lang_obj')
# get dictionary of datasets
dataset_dict = {
'train':
nmt_dataset.LanguagePair(source_name=source_name,
target_name=target_name,
filepath=path_to_train_data,
lang_obj_path=saved_language_model_dir,
minimum_count=1),
'dev':
nmt_dataset.LanguagePair(source_name=source_name,
target_name=target_name,
filepath=path_to_dev_data,
lang_obj_path=saved_language_model_dir,
minimum_count=1)
}
# get max sentence length by 99% percentile
MAX_LEN = int(dataset_dict['train'].main_df['source_len'].quantile(0.9999))
batchSize = parser.batch_size
log.info("Batch size = {}.".format(batchSize))
dataloader_dict = {
'train':
DataLoader(dataset_dict['train'],
batch_size=batchSize,
collate_fn=partial(nmt_dataset.vocab_collate_func,
MAX_LEN=MAX_LEN),
shuffle=True,
num_workers=0),
'dev':
DataLoader(dataset_dict['dev'],
batch_size=batchSize,
collate_fn=partial(nmt_dataset.vocab_collate_func,
MAX_LEN=MAX_LEN),
shuffle=True,
num_workers=0)
}
# Configuration
source_lang_obj = dataset_dict['train'].source_lang_obj
target_lang_obj = dataset_dict['train'].target_lang_obj
source_vocab = dataset_dict['train'].source_lang_obj.n_words
target_vocab = dataset_dict['train'].target_lang_obj.n_words
hidden_size = parser.hidden_size
rnn_layers = parser.rnn_layers
lr = parser.learning_rate
longest_label = parser.longest_label
gradient_clip = parser.gradient_clip
num_epochs = parser.epochs
encoder_attention = parser.encoder_attention
self_attention = parser.self_attention
log.info("encoder_attention = {}, self_attention = {}".format(
encoder_attention, self_attention))
# encoder model
encoder_transformer = nnet_models_new.EncoderTransformer(
source_vocab, MAX_LEN, hidden_size, rnn_layers)
# decoder model
decoder_encoderattn = nnet_models_new.Decoder_SelfAttn(
output_size=target_vocab,
hidden_size=hidden_size,
encoder_attention=encoder_attention,
self_attention=self_attention)
# seq2seq model
nmt_encoderattn = nnet_models_new.seq2seq(
encoder_transformer,
decoder_encoderattn,
lr=lr,
hiddensize=hidden_size,
numlayers=hidden_size,
target_lang=dataset_dict['train'].target_lang_obj,
longest_label=longest_label,
clip=gradient_clip,
device=device)
log.info(
"Seq2Seq Model with the following parameters: encoder_attention = {}, self_attention = {}, batch_size = {}, learning_rate = {}, hidden_size = {}, rnn_layers = {}, lr = {}, longest_label = {}, gradient_clip = {}, num_epochs = {}, source_name = {}, target_name = {}"
.format(encoder_attention, self_attention, batchSize, lr, hidden_size,
rnn_layers, lr, longest_label, gradient_clip, num_epochs,
source_name, target_name))
# do we want to train again?
train_again = False
modelname = 'encoderattn'
# check if there is a saved model and if we want to train again
if os.path.exists(utils.get_full_filepath(
saved_models_dir, modelname)) and (not train_again):
log.info("Retrieving saved model from {}".format(
utils.get_full_filepath(saved_models_dir, modelname)))
nmt_rnn = torch.load(
utils.get_full_filepath(saved_models_dir, modelname))
# train model again
else:
log.info("Check if this path exists: {}".format(
utils.get_full_filepath(saved_models_dir, modelname)))
log.info("It does not exist! Starting to train...")
utils.train_model(dataloader_dict,
nmt_encoderattn,
num_epochs=num_epochs,
saved_model_path=saved_models_dir,
enc_type='encoderattn_test')
log.info("Total time is: {} min : {} s".format((time.time() - start) // 60,
(time.time() - start) % 60))
def main():
"""
Main method for experiment
"""
start = time.time()
repository = os.path.dirname(os.path.dirname(os.path.abspath(__file__)))
parser = args.parse_args()
# run some checks on arguments
check_args(parser)
# format logging
log_name = os.path.join(
parser.run_log,
'{}_run_log_{}.log'.format(parser.experiment,
dt.now().strftime("%Y%m%d_%H%M")))
log.basicConfig(filename=log_name,
format='%(asctime)s | %(name)s -- %(message)s',
level=log.INFO)
os.chmod(log_name, parser.access_mode)
# set devise to CPU if available
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
log.info("Device is {}".format(device))
# set seed for replication
random.seed(parser.seed)
np.random.seed(parser.seed)
torch.manual_seed(parser.seed)
if torch.cuda.is_available():
torch.cuda.manual_seed_all(parser.seed)
log.info("Starting experiment {} on {} with model {}".format(
parser.experiment, device, parser.model))
print("{}".format(parser.experiment))
# set tokenizer and config from Huggingface
tokenizer = transformers.AutoTokenizer.from_pretrained(
parser.model, do_lower_case=parser.do_lower_case)
config = transformers.AutoConfig.from_pretrained(parser.model)
# create IO object and import data
cache_head = os.path.join(parser.save_dir, 'cached_data')
cache_dir = os.path.join(cache_head, parser.model)
if not os.path.exists(cache_head):
os.mkdir(cache_head)
if not os.path.exists(cache_dir):
os.mkdir(cache_dir)
data_handler = myio.IO(parser.data_dir,
cache_dir,
tokenizer,
parser.max_seq_length,
parser.doc_stride,
parser.max_query_length,
batch_size=parser.batch_size,
shuffle=True,
cache=True)
# =============================================================================
# BASELINE
# =============================================================================
# parse continual learning curriculum
parser.continual_curriculum = parser.continual_curriculum.split(',')
# create BERT model
BERTmodel = model.QAModel(
parser.model,
config,
load_rln=parser.load_rln,
rln_weights=parser.rln_weights,
)
# create learner object for BERT model
trainer = learner.Learner(
parser.access_mode,
parser.fp16,
parser.fp16_opt_level,
BERTmodel,
parser.model,
device,
data_handler,
parser.save_dir,
parser.n_best_size,
parser.max_answer_length,
parser.do_lower_case,
parser.verbose_logging,
parser.version_2_with_negative,
parser.null_score_diff_threshold,
max_steps=parser.fine_tune_steps,
log_int=parser.logging_steps,
best_int=parser.save_steps,
verbose_int=parser.verbose_steps,
max_grad_norm=parser.max_grad_norm,
optimizer=None,
weight_decay=parser.weight_decay,
lr=parser.learning_rate,
eps=parser.adam_epsilon,
warmup_steps=parser.warmup_steps,
freeze_embeddings=parser.freeze_embeddings,
)
# create continual learning object and perform continual learning
c_learner = cont_learning.ContLearner(
parser.model,
'BERT',
trainer,
curriculum=parser.continual_curriculum,
fine_tune_prev=not parser.no_prev_fine_tune)
log.info("Starting Continual Learning")
if not parser.no_cont_learning:
c_learner.c_learn(rln_only=parser.carry_rln_only)
if len(parser.continual_curriculum) > 1 and not parser.no_forget_eval:
c_learner.evaluate_forgetting(rln_only=parser.carry_rln_only)
log.info("Generating Plot")
# generate BERT plot
now = dt.now().strftime("%Y%m%d_%H%M")
# create results folders if not generated
plot_dir = os.path.join(parser.save_dir, "plots")
json_dir = os.path.join(parser.save_dir, "json_results")
if not os.path.exists(plot_dir):
os.mkdir(plot_dir)
if not os.path.exists(json_dir):
os.mkdir(json_dir)
# plot results and save
plot = analyze.plot_learning(c_learner.scores,
x_tick_int=2 * parser.logging_steps,
iterations=parser.fine_tune_steps)
plot_name = os.path.join(
plot_dir, "baseline_{}_{}_{}.png".format(parser.experiment,
parser.model, now))
plot.savefig(plot_name)
os.chmod(plot_name, parser.access_mode)
log.info("Plot saved at: {}".format(plot_name))
# write data to json
baseline_results_name = os.path.join(
json_dir, "baseline_{}_{}_{}.json".format(parser.experiment,
parser.model, now))
with open(baseline_results_name, 'w') as fw:
json.dump(c_learner.scores, fw)
os.chmod(baseline_results_name, parser.access_mode)
log.info(
"Baseline results written to: {}".format(baseline_results_name))
log.info("Total time is: {}min : {}s".format((time.time() - start) // 60,
(time.time() - start) % 60))
def main():
"""
Main method for experiment
"""
start = time.time()
repository = os.path.dirname(os.path.dirname(os.path.abspath(__file__)))
parser = args.parse_args()
if parser.run_log == 'log':
parser.run_log = os.path.join(parser.save_dir, 'log')
if not os.path.exists(parser.run_log):
os.mkdir(parser.run_log)
# run some checks on arguments
check_args(parser)
# format logging
log_name = os.path.join(
parser.run_log,
'{}_run_log_{}.log'.format(parser.experiment,
dt.now().strftime("%Y%m%d_%H%M")))
log.basicConfig(filename=log_name,
format='%(asctime)s | %(name)s -- %(message)s',
level=log.INFO)
os.chmod(log_name, parser.access_mode)
# set devise to CPU if available
device = torch.device("cuda:0" if torch.cuda.is_available() else "cpu")
log.info("Device is {}".format(device))
# set seed for replication
random.seed(parser.seed)
np.random.seed(parser.seed)
torch.manual_seed(parser.seed)
if torch.cuda.is_available():
torch.cuda.manual_seed_all(parser.seed)
log.info("Starting experiment {} on {}".format(parser.experiment, device))
data_handler = myio.IO(
data_dir=parser.data_dir, # directory storing data
batch_size=parser.batch_size, # batch size
shuffle=not parser.no_shuffle, # whether to shuffle training data
split=parser.val_split, # percentage of data for validation
)
# TODO:
# create model
my_model = model.Model(
road_lambda=parser.road_lambda, # relative weight of road map loss
box_lambda=parser.box_lambda, # relative weight of bounding box loss
preload_backbone=parser.preload, # whether to load pretrained weights
backbone_weights=parser.
preload_weights, # pretrained backbone weights if needed
)
# create learner
trainer = learner.Learner(
access_mode=parser.access_mode, # os access mode for created files
experiment_name=parser.experiment, # name of experiment
model=my_model, # model
device=device, # device to run experiment
myio=data_handler, # myio.IO object for loading data
save_dir=parser.save_dir, # directory to save results
max_steps=parser.training_steps, # maximum number of update steps
best_int=parser.save_steps, # interval for checking weights
verbose_int=parser.verbose_steps, # interval for logging information
max_grad_norm=parser.
max_grad_norm, # maximum gradients to avoid exploding gradients
optimizer=None, # optimizer for training
weight_decay=parser.weight_decay, # weight decay if using
lr=parser.learning_rate, # learning rate
eps=parser.adam_epsilon, # epsilon to use for adam
accumulate_int=parser.
accumulate_int, # number of steps to accumulate gradients before stepping
batch_size=parser.batch_size, # batch size
warmup_pct=parser.
pct_start, # percent of updates used to warm-up learning rate
save=not parser.no_save, # whether to save weights
patience=parser.
patience, # number of checks without improvement before early stop
)
# train model
results = trainer.train(labeled=not parser.no_label, debug=parser.debug)
results["experiment"] = parser.experiment
# write results to "results.jsonl"
results_name = os.path.join(parser.save_dir, "results.jsonl")
with open(results_name, 'a') as f:
f.write(json.dumps(results) + "\n")
os.chmod(results_name, parser.access_mode)
log.info("Results written to: {}".format(results_name))
log.info("Total time is: {} min : {} sec".format(
(time.time() - start) // 60, (time.time() - start) % 60))
