def __init__(self, device, n_classes, **kwargs):
self.inner_lr = kwargs.get('inner_lr')
self.meta_lr = kwargs.get('meta_lr')
self.write_prob = kwargs.get('write_prob')
self.replay_rate = kwargs.get('replay_rate')
self.replay_every = kwargs.get('replay_every')
self.device = device
self.nm = TransformerNeuromodulator(model_name=kwargs.get('model'),
device=device)
self.pn = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=n_classes,
max_length=kwargs.get('max_length'),
device=device)
self.memory = ReplayMemory(write_prob=self.write_prob, tuple_size=2)
self.loss_fn = nn.CrossEntropyLoss()
logger.info('Loaded {} as NM'.format(self.nm.__class__.__name__))
logger.info('Loaded {} as PN'.format(self.pn.__class__.__name__))
meta_params = [p for p in self.nm.parameters() if p.requires_grad] + \
[p for p in self.pn.parameters() if p.requires_grad]
self.meta_optimizer = AdamW(meta_params, lr=self.meta_lr)
inner_params = [p for p in self.pn.parameters() if p.requires_grad]
self.inner_optimizer = optim.SGD(inner_params, lr=self.inner_lr)
def __init__(self, device, n_classes, training_mode, **kwargs):
self.lr = kwargs.get('lr', 3e-5)
self.device = device
self.training_mode = training_mode
self.model = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=n_classes,
max_length=kwargs.get('max_length'),
device=device)
logger.info('Loaded {} as model'.format(self.model.__class__.__name__))
self.loss_fn = nn.CrossEntropyLoss()
self.optimizer = AdamW(
[p for p in self.model.parameters() if p.requires_grad],
lr=self.lr)
def __init__(self, device, training_mode, **kwargs):
self.lr = kwargs.get('lr', 3e-5)
self.device = device
self.training_mode = training_mode
self.model = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=1,
max_length=kwargs.get('max_length'),
device=device)
params = [p for p in self.model.parameters() if p.requires_grad]
self.optimizer = AdamW(params, lr=self.lr)
logger.info('Loaded {} as the model'.format(self.model.__class__.__name__))
self.loss_fn = nn.BCEWithLogitsLoss()
def __init__(self, device, **kwargs):
self.lr = kwargs.get('lr', 3e-5)
self.write_prob = kwargs.get('write_prob')
self.replay_rate = kwargs.get('replay_rate')
self.replay_every = kwargs.get('replay_every')
self.device = device
self.model = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=1,
max_length=kwargs.get('max_length'),
device=device)
self.memory = ReplayMemory(write_prob=self.write_prob, tuple_size=3)
logger.info('Loaded {} as the model'.format(self.model.__class__.__name__))
params = [p for p in self.model.parameters() if p.requires_grad]
self.optimizer = AdamW(params, lr=self.lr)
self.loss_fn = nn.BCEWithLogitsLoss()
def __init__(self, device, n_classes, **kwargs):
self.lr = kwargs.get('lr', 3e-5)
self.write_prob = kwargs.get('write_prob')
self.replay_rate = kwargs.get('replay_rate')
self.replay_every = kwargs.get('replay_every')
self.device = device
self.model = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=n_classes,
max_length=kwargs.get('max_length'),
device=device,
hebbian=kwargs.get('hebbian'))
self.memory = ReplayMemory(write_prob=self.write_prob, tuple_size=2)
logger.info('Loaded {} as model'.format(self.model.__class__.__name__))
self.loss_fn = nn.CrossEntropyLoss()
self.optimizer = AdamW(
[p for p in self.model.parameters() if p.requires_grad],
lr=self.lr)
def __init__(self, device, **kwargs):
self.inner_lr = kwargs.get('inner_lr')
self.meta_lr = kwargs.get('meta_lr')
self.write_prob = kwargs.get('write_prob')
self.replay_rate = kwargs.get('replay_rate')
self.replay_every = kwargs.get('replay_every')
self.device = device
self.pn = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=1,
max_length=kwargs.get('max_length'),
device=device,
hebbian=kwargs.get('hebbian'))
logger.info('Loaded {} as PN'.format(self.pn.__class__.__name__))
meta_params = [p for p in self.pn.parameters() if p.requires_grad]
self.meta_optimizer = AdamW(meta_params, lr=self.meta_lr)
self.memory = ReplayMemory(write_prob=self.write_prob, tuple_size=3)
self.loss_fn = nn.BCEWithLogitsLoss()
inner_params = [p for p in self.pn.parameters() if p.requires_grad]
self.inner_optimizer = optim.SGD(inner_params, lr=self.inner_lr)
class AGEM:
def __init__(self, device, **kwargs):
self.lr = kwargs.get('lr', 3e-5)
self.write_prob = kwargs.get('write_prob')
self.replay_rate = kwargs.get('replay_rate')
self.replay_every = kwargs.get('replay_every')
self.device = device
self.model = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=1,
max_length=kwargs.get('max_length'),
device=device,
hebbian=kwargs.get('hebbian'))
self.memory = ReplayMemory(write_prob=self.write_prob, tuple_size=3)
logger.info('Loaded {} as the model'.format(
self.model.__class__.__name__))
params = [p for p in self.model.parameters() if p.requires_grad]
self.optimizer = AdamW(params, lr=self.lr)
self.loss_fn = nn.BCEWithLogitsLoss()
def save_model(self, model_path):
checkpoint = self.model.state_dict()
torch.save(checkpoint, model_path)
def load_model(self, model_path):
checkpoint = torch.load(model_path)
self.model.load_state_dict(checkpoint)
def compute_grad(self, orig_grad, ref_grad):
with torch.no_grad():
flat_orig_grad = torch.cat([torch.flatten(x) for x in orig_grad])
flat_ref_grad = torch.cat([torch.flatten(x) for x in ref_grad])
dot_product = torch.dot(flat_orig_grad, flat_ref_grad)
if dot_product >= 0:
return orig_grad
proj_component = dot_product / torch.dot(flat_ref_grad,
flat_ref_grad)
modified_grad = [
o - proj_component * r for (o, r) in zip(orig_grad, ref_grad)
]
return modified_grad
def train(self, dataloader, n_epochs, log_freq):
self.model.train()
for epoch in range(n_epochs):
all_losses, all_predictions, all_labels = [], [], []
iter = 0
for text, label, candidates in dataloader:
replicated_text, replicated_relations, ranking_label = datasets.utils.replicate_rel_data(
text, label, candidates)
input_dict = self.model.encode_text(
list(zip(replicated_text, replicated_relations)))
output = self.model(input_dict)
targets = torch.tensor(ranking_label).float().unsqueeze(1).to(
self.device)
loss = self.loss_fn(output, targets)
self.optimizer.zero_grad()
params = [
p for p in self.model.parameters() if p.requires_grad
]
orig_grad = torch.autograd.grad(loss, params)
mini_batch_size = len(label)
replay_freq = self.replay_every // mini_batch_size
replay_steps = int(self.replay_every * self.replay_rate /
mini_batch_size)
if self.replay_rate != 0 and (iter + 1) % replay_freq == 0:
ref_grad_sum = None
for _ in range(replay_steps):
ref_text, ref_label, ref_candidates = self.memory.read_batch(
batch_size=mini_batch_size)
replicated_ref_text, replicated_ref_relations, ref_ranking_label = datasets.utils.replicate_rel_data(
ref_text, ref_label, ref_candidates)
ref_input_dict = self.model.encode_text(
list(
zip(replicated_ref_text,
replicated_ref_relations)))
ref_output = self.model(ref_input_dict)
ref_targets = torch.tensor(
ref_ranking_label).float().unsqueeze(1).to(
self.device)
ref_loss = self.loss_fn(ref_output, ref_targets)
ref_grad = torch.autograd.grad(ref_loss, params)
if ref_grad_sum is None:
ref_grad_sum = ref_grad
else:
ref_grad_sum = [
x + y
for (x, y) in zip(ref_grad, ref_grad_sum)
]
final_grad = self.compute_grad(orig_grad, ref_grad_sum)
else:
final_grad = orig_grad
for param, grad in zip(params, final_grad):
param.grad = grad.data
self.optimizer.step()
loss = loss.item()
pred, true_labels = models.utils.make_rel_prediction(
output, ranking_label)
all_losses.append(loss)
all_predictions.extend(pred.tolist())
all_labels.extend(true_labels.tolist())
iter += 1
self.memory.write_batch(text, label, candidates)
if iter % log_freq == 0:
acc = models.utils.calculate_accuracy(
all_predictions, all_labels)
logger.info(
'Epoch {} metrics: Loss = {:.4f}, accuracy = {:.4f}'.
format(epoch + 1, np.mean(all_losses), acc))
all_losses, all_predictions, all_labels = [], [], []
def evaluate(self, dataloader):
all_losses, all_predictions, all_labels = [], [], []
self.model.eval()
for text, label, candidates in dataloader:
replicated_text, replicated_relations, ranking_label = datasets.utils.replicate_rel_data(
text, label, candidates)
with torch.no_grad():
input_dict = self.model.encode_text(
list(zip(replicated_text, replicated_relations)))
output = self.model(input_dict)
pred, true_labels = models.utils.make_rel_prediction(
output, ranking_label)
all_predictions.extend(pred.tolist())
all_labels.extend(true_labels.tolist())
acc = models.utils.calculate_accuracy(all_predictions, all_labels)
return acc
def training(self, train_datasets, **kwargs):
n_epochs = kwargs.get('n_epochs', 1)
log_freq = kwargs.get('log_freq', 20)
mini_batch_size = kwargs.get('mini_batch_size')
train_dataset = data.ConcatDataset(train_datasets)
train_dataloader = data.DataLoader(
train_dataset,
batch_size=mini_batch_size,
shuffle=False,
collate_fn=datasets.utils.rel_encode)
self.train(dataloader=train_dataloader,
n_epochs=n_epochs,
log_freq=log_freq)
def testing(self, test_dataset, **kwargs):
mini_batch_size = kwargs.get('mini_batch_size')
test_dataloader = data.DataLoader(test_dataset,
batch_size=mini_batch_size,
shuffle=False,
collate_fn=datasets.utils.rel_encode)
acc = self.evaluate(dataloader=test_dataloader)
logger.info('Overall test metrics: Accuracy = {:.4f}'.format(acc))
return acc
class Baseline:
def __init__(self, device, training_mode, **kwargs):
self.lr = kwargs.get('lr', 3e-5)
self.device = device
self.training_mode = training_mode
self.model = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=1,
max_length=kwargs.get('max_length'),
device=device)
params = [p for p in self.model.parameters() if p.requires_grad]
self.optimizer = AdamW(params, lr=self.lr)
logger.info('Loaded {} as the model'.format(self.model.__class__.__name__))
self.loss_fn = nn.BCEWithLogitsLoss()
def save_model(self, model_path):
checkpoint = self.model.state_dict()
torch.save(checkpoint, model_path)
def load_model(self, model_path):
checkpoint = torch.load(model_path)
self.model.load_state_dict(checkpoint)
def train(self, dataloader, n_epochs, log_freq):
self.model.train()
for epoch in range(n_epochs):
all_losses, all_predictions, all_labels = [], [], []
iter = 0
for text, label, candidates in dataloader:
replicated_text, replicated_relations, ranking_label = datasets.utils.replicate_rel_data(text, label,
candidates)
input_dict = self.model.encode_text(list(zip(replicated_text, replicated_relations)))
output = self.model(input_dict)
targets = torch.tensor(ranking_label).float().unsqueeze(1).to(self.device)
loss = self.loss_fn(output, targets)
self.optimizer.zero_grad()
loss.backward()
self.optimizer.step()
loss = loss.item()
pred, true_labels = models.utils.make_rel_prediction(output, ranking_label)
all_losses.append(loss)
all_predictions.extend(pred.tolist())
all_labels.extend(true_labels.tolist())
iter += 1
if iter % log_freq == 0:
acc = models.utils.calculate_accuracy(all_predictions, all_labels)
logger.info(
'Epoch {} metrics: Loss = {:.4f}, accuracy = {:.4f}'.format(epoch + 1, np.mean(all_losses), acc))
all_losses, all_predictions, all_labels = [], [], []
def evaluate(self, dataloader):
all_losses, all_predictions, all_labels = [], [], []
self.model.eval()
for text, label, candidates in dataloader:
replicated_text, replicated_relations, ranking_label = datasets.utils.replicate_rel_data(text, label,
candidates)
with torch.no_grad():
input_dict = self.model.encode_text(list(zip(replicated_text, replicated_relations)))
output = self.model(input_dict)
pred, true_labels = models.utils.make_rel_prediction(output, ranking_label)
all_predictions.extend(pred.tolist())
all_labels.extend(true_labels.tolist())
acc = models.utils.calculate_accuracy(all_predictions, all_labels)
return acc
def training(self, train_datasets, **kwargs):
n_epochs = kwargs.get('n_epochs', 1)
log_freq = kwargs.get('log_freq', 20)
mini_batch_size = kwargs.get('mini_batch_size')
if self.training_mode == 'sequential':
for cluster_idx, train_dataset in enumerate(train_datasets):
logger.info('Training on cluster {}'.format(cluster_idx + 1))
train_dataloader = data.DataLoader(train_dataset, batch_size=mini_batch_size, shuffle=False,
collate_fn=datasets.utils.rel_encode)
self.train(dataloader=train_dataloader, n_epochs=n_epochs, log_freq=log_freq)
elif self.training_mode == 'multi_task':
train_dataset = data.ConcatDataset(train_datasets)
logger.info('Training multi-task model on all datasets')
train_dataloader = data.DataLoader(train_dataset, batch_size=mini_batch_size, shuffle=True,
collate_fn=datasets.utils.rel_encode)
self.train(dataloader=train_dataloader, n_epochs=n_epochs, log_freq=log_freq)
def testing(self, test_dataset, **kwargs):
mini_batch_size = kwargs.get('mini_batch_size')
test_dataloader = data.DataLoader(test_dataset, batch_size=mini_batch_size, shuffle=False,
collate_fn=datasets.utils.rel_encode)
acc = self.evaluate(dataloader=test_dataloader)
logger.info('Overall test metrics: Accuracy = {:.4f}'.format(acc))
return acc
class ANML:
def __init__(self, device, n_classes, **kwargs):
self.inner_lr = kwargs.get('inner_lr')
self.meta_lr = kwargs.get('meta_lr')
self.write_prob = kwargs.get('write_prob')
self.replay_rate = kwargs.get('replay_rate')
self.replay_every = kwargs.get('replay_every')
self.device = device
self.nm = TransformerNeuromodulator(model_name=kwargs.get('model'),
device=device)
self.pn = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=n_classes,
max_length=kwargs.get('max_length'),
device=device)
self.memory = ReplayMemory(write_prob=self.write_prob, tuple_size=2)
self.loss_fn = nn.CrossEntropyLoss()
logger.info('Loaded {} as NM'.format(self.nm.__class__.__name__))
logger.info('Loaded {} as PN'.format(self.pn.__class__.__name__))
meta_params = [p for p in self.nm.parameters() if p.requires_grad] + \
[p for p in self.pn.parameters() if p.requires_grad]
self.meta_optimizer = AdamW(meta_params, lr=self.meta_lr)
inner_params = [p for p in self.pn.parameters() if p.requires_grad]
self.inner_optimizer = optim.SGD(inner_params, lr=self.inner_lr)
def save_model(self, model_path):
checkpoint = {'nm': self.nm.state_dict(), 'pn': self.pn.state_dict()}
torch.save(checkpoint, model_path)
def load_model(self, model_path):
checkpoint = torch.load(model_path)
self.nm.load_state_dict(checkpoint['nm'])
self.pn.load_state_dict(checkpoint['pn'])
def evaluate(self, dataloader, updates, mini_batch_size):
support_set = []
for _ in range(updates):
text, labels = self.memory.read_batch(batch_size=mini_batch_size)
support_set.append((text, labels))
with higher.innerloop_ctx(self.pn,
self.inner_optimizer,
copy_initial_weights=False,
track_higher_grads=False) as (fpn, diffopt):
# Inner loop
task_predictions, task_labels = [], []
support_loss = []
for text, labels in support_set:
labels = torch.tensor(labels).to(self.device)
input_dict = self.pn.encode_text(text)
repr = fpn(input_dict, out_from='transformers')
modulation = self.nm(input_dict)
output = fpn(repr * modulation, out_from='linear')
loss = self.loss_fn(output, labels)
diffopt.step(loss)
pred = models.utils.make_prediction(output.detach())
support_loss.append(loss.item())
task_predictions.extend(pred.tolist())
task_labels.extend(labels.tolist())
acc, prec, rec, f1 = models.utils.calculate_metrics(
task_predictions, task_labels)
logger.info(
'Support set metrics: Loss = {:.4f}, accuracy = {:.4f}, precision = {:.4f}, '
'recall = {:.4f}, F1 score = {:.4f}'.format(
np.mean(support_loss), acc, prec, rec, f1))
all_losses, all_predictions, all_labels = [], [], []
for text, labels in dataloader:
labels = torch.tensor(labels).to(self.device)
input_dict = self.pn.encode_text(text)
with torch.no_grad():
repr = fpn(input_dict, out_from='transformers')
modulation = self.nm(input_dict)
output = fpn(repr * modulation, out_from='linear')
loss = self.loss_fn(output, labels)
loss = loss.item()
pred = models.utils.make_prediction(output.detach())
all_losses.append(loss)
all_predictions.extend(pred.tolist())
all_labels.extend(labels.tolist())
acc, prec, rec, f1 = models.utils.calculate_metrics(
all_predictions, all_labels)
logger.info(
'Test metrics: Loss = {:.4f}, accuracy = {:.4f}, precision = {:.4f}, recall = {:.4f}, '
'F1 score = {:.4f}'.format(np.mean(all_losses), acc, prec, rec,
f1))
return acc, prec, rec, f1
def training(self, train_datasets, **kwargs):
updates = kwargs.get('updates')
mini_batch_size = kwargs.get('mini_batch_size')
if self.replay_rate != 0:
replay_batch_freq = self.replay_every // mini_batch_size
replay_freq = int(
math.ceil((replay_batch_freq + 1) / (updates + 1)))
replay_steps = int(self.replay_every * self.replay_rate /
mini_batch_size)
else:
replay_freq = 0
replay_steps = 0
logger.info('Replay frequency: {}'.format(replay_freq))
logger.info('Replay steps: {}'.format(replay_steps))
concat_dataset = data.ConcatDataset(train_datasets)
train_dataloader = iter(
data.DataLoader(concat_dataset,
batch_size=mini_batch_size,
shuffle=False,
collate_fn=datasets.utils.batch_encode))
episode_id = 0
while True:
self.inner_optimizer.zero_grad()
support_loss, support_acc, support_prec, support_rec, support_f1 = [], [], [], [], []
with higher.innerloop_ctx(self.pn,
self.inner_optimizer,
copy_initial_weights=False,
track_higher_grads=False) as (fpn,
diffopt):
# Inner loop
support_set = []
task_predictions, task_labels = [], []
for _ in range(updates):
try:
text, labels = next(train_dataloader)
support_set.append((text, labels))
except StopIteration:
logger.info(
'Terminating training as all the data is seen')
return
for text, labels in support_set:
labels = torch.tensor(labels).to(self.device)
input_dict = self.pn.encode_text(text)
repr = fpn(input_dict, out_from='transformers')
modulation = self.nm(input_dict)
output = fpn(repr * modulation, out_from='linear')
loss = self.loss_fn(output, labels)
diffopt.step(loss)
pred = models.utils.make_prediction(output.detach())
support_loss.append(loss.item())
task_predictions.extend(pred.tolist())
task_labels.extend(labels.tolist())
self.memory.write_batch(text, labels)
acc, prec, rec, f1 = models.utils.calculate_metrics(
task_predictions, task_labels)
logger.info(
'Episode {} support set: Loss = {:.4f}, accuracy = {:.4f}, precision = {:.4f}, '
'recall = {:.4f}, F1 score = {:.4f}'.format(
episode_id + 1, np.mean(support_loss), acc, prec, rec,
f1))
# Outer loop
query_loss, query_acc, query_prec, query_rec, query_f1 = [], [], [], [], []
query_set = []
if self.replay_rate != 0 and (episode_id +
1) % replay_freq == 0:
for _ in range(replay_steps):
text, labels = self.memory.read_batch(
batch_size=mini_batch_size)
query_set.append((text, labels))
else:
try:
text, labels = next(train_dataloader)
query_set.append((text, labels))
self.memory.write_batch(text, labels)
except StopIteration:
logger.info(
'Terminating training as all the data is seen')
return
for text, labels in query_set:
labels = torch.tensor(labels).to(self.device)
input_dict = self.pn.encode_text(text)
repr = fpn(input_dict, out_from='transformers')
modulation = self.nm(input_dict)
output = fpn(repr * modulation, out_from='linear')
loss = self.loss_fn(output, labels)
query_loss.append(loss.item())
pred = models.utils.make_prediction(output.detach())
acc, prec, rec, f1 = models.utils.calculate_metrics(
pred.tolist(), labels.tolist())
query_acc.append(acc)
query_prec.append(prec)
query_rec.append(rec)
query_f1.append(f1)
# NM meta gradients
nm_params = [
p for p in self.nm.parameters() if p.requires_grad
]
meta_nm_grads = torch.autograd.grad(loss,
nm_params,
retain_graph=True)
for param, meta_grad in zip(nm_params, meta_nm_grads):
if param.grad is not None:
param.grad += meta_grad.detach()
else:
param.grad = meta_grad.detach()
# PN meta gradients
pn_params = [
p for p in fpn.parameters() if p.requires_grad
]
meta_pn_grads = torch.autograd.grad(loss, pn_params)
pn_params = [
p for p in self.pn.parameters() if p.requires_grad
]
for param, meta_grad in zip(pn_params, meta_pn_grads):
if param.grad is not None:
param.grad += meta_grad.detach()
else:
param.grad = meta_grad.detach()
# Meta optimizer step
self.meta_optimizer.step()
self.meta_optimizer.zero_grad()
logger.info(
'Episode {} query set: Loss = {:.4f}, accuracy = {:.4f}, precision = {:.4f}, '
'recall = {:.4f}, F1 score = {:.4f}'.format(
episode_id + 1, np.mean(query_loss),
np.mean(query_acc), np.mean(query_prec),
np.mean(query_rec), np.mean(query_f1)))
episode_id += 1
def testing(self, test_datasets, **kwargs):
updates = kwargs.get('updates')
mini_batch_size = kwargs.get('mini_batch_size')
accuracies, precisions, recalls, f1s = [], [], [], []
for test_dataset in test_datasets:
logger.info('Testing on {}'.format(
test_dataset.__class__.__name__))
test_dataloader = data.DataLoader(
test_dataset,
batch_size=mini_batch_size,
shuffle=False,
collate_fn=datasets.utils.batch_encode)
acc, prec, rec, f1 = self.evaluate(dataloader=test_dataloader,
updates=updates,
mini_batch_size=mini_batch_size)
accuracies.append(acc)
precisions.append(prec)
recalls.append(rec)
f1s.append(f1)
logger.info(
'Overall test metrics: Accuracy = {:.4f}, precision = {:.4f}, recall = {:.4f}, '
'F1 score = {:.4f}'.format(np.mean(accuracies),
np.mean(precisions), np.mean(recalls),
np.mean(f1s)))
return accuracies
class Replay:
def __init__(self, device, n_classes, **kwargs):
self.lr = kwargs.get('lr', 3e-5)
self.write_prob = kwargs.get('write_prob')
self.replay_rate = kwargs.get('replay_rate')
self.replay_every = kwargs.get('replay_every')
self.device = device
self.model = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=n_classes,
max_length=kwargs.get('max_length'),
device=device,
hebbian=kwargs.get('hebbian'))
self.memory = ReplayMemory(write_prob=self.write_prob, tuple_size=2)
logger.info('Loaded {} as model'.format(self.model.__class__.__name__))
self.loss_fn = nn.CrossEntropyLoss()
self.optimizer = AdamW(
[p for p in self.model.parameters() if p.requires_grad],
lr=self.lr)
def save_model(self, model_path):
checkpoint = self.model.state_dict()
torch.save(checkpoint, model_path)
def load_model(self, model_path):
checkpoint = torch.load(model_path)
self.model.load_state_dict(checkpoint)
def train(self, dataloader, n_epochs, log_freq):
self.model.train()
for epoch in range(n_epochs):
all_losses, all_predictions, all_labels = [], [], []
iter = 0
for text, labels in dataloader:
labels = torch.tensor(labels).to(self.device)
input_dict = self.model.encode_text(text)
output = self.model(input_dict)
loss = self.loss_fn(output, labels)
self.optimizer.zero_grad()
loss.backward()
self.optimizer.step()
mini_batch_size = len(labels)
replay_freq = self.replay_every // mini_batch_size
replay_steps = int(self.replay_every * self.replay_rate /
mini_batch_size)
if self.replay_rate != 0 and (iter + 1) % replay_freq == 0:
self.optimizer.zero_grad()
for _ in range(replay_steps):
ref_text, ref_labels = self.memory.read_batch(
batch_size=mini_batch_size)
ref_labels = torch.tensor(ref_labels).to(self.device)
ref_input_dict = self.model.encode_text(ref_text)
ref_output = self.model(ref_input_dict)
ref_loss = self.loss_fn(ref_output, ref_labels)
ref_loss.backward()
params = [
p for p in self.model.parameters() if p.requires_grad
]
torch.nn.utils.clip_grad_norm(params, 25)
self.optimizer.step()
loss = loss.item()
pred = models.utils.make_prediction(output.detach())
all_losses.append(loss)
all_predictions.extend(pred.tolist())
all_labels.extend(labels.tolist())
iter += 1
self.memory.write_batch(text, labels)
if iter % log_freq == 0:
acc, prec, rec, f1 = models.utils.calculate_metrics(
all_predictions, all_labels)
logger.info(
'Epoch {} metrics: Loss = {:.4f}, accuracy = {:.4f}, precision = {:.4f}, recall = {:.4f}, '
'F1 score = {:.4f}'.format(epoch + 1,
np.mean(all_losses), acc,
prec, rec, f1))
all_losses, all_predictions, all_labels = [], [], []
def evaluate(self, dataloader):
all_losses, all_predictions, all_labels = [], [], []
self.model.eval()
for text, labels in dataloader:
labels = torch.tensor(labels).to(self.device)
input_dict = self.model.encode_text(text)
with torch.no_grad():
output = self.model(input_dict)
loss = self.loss_fn(output, labels)
loss = loss.item()
pred = models.utils.make_prediction(output.detach())
all_losses.append(loss)
all_predictions.extend(pred.tolist())
all_labels.extend(labels.tolist())
acc, prec, rec, f1 = models.utils.calculate_metrics(
all_predictions, all_labels)
logger.info(
'Test metrics: Loss = {:.4f}, accuracy = {:.4f}, precision = {:.4f}, recall = {:.4f}, '
'F1 score = {:.4f}'.format(np.mean(all_losses), acc, prec, rec,
f1))
return acc, prec, rec, f1
def training(self, train_datasets, **kwargs):
n_epochs = kwargs.get('n_epochs', 1)
log_freq = kwargs.get('log_freq', 50)
mini_batch_size = kwargs.get('mini_batch_size')
train_dataset = data.ConcatDataset(train_datasets)
train_dataloader = data.DataLoader(
train_dataset,
batch_size=mini_batch_size,
shuffle=False,
collate_fn=datasets.utils.batch_encode)
self.train(dataloader=train_dataloader,
n_epochs=n_epochs,
log_freq=log_freq)
def testing(self, test_datasets, **kwargs):
mini_batch_size = kwargs.get('mini_batch_size')
accuracies, precisions, recalls, f1s = [], [], [], []
for test_dataset in test_datasets:
logger.info('Testing on {}'.format(
test_dataset.__class__.__name__))
test_dataloader = data.DataLoader(
test_dataset,
batch_size=mini_batch_size,
shuffle=False,
collate_fn=datasets.utils.batch_encode)
acc, prec, rec, f1 = self.evaluate(dataloader=test_dataloader)
accuracies.append(acc)
precisions.append(prec)
recalls.append(rec)
f1s.append(f1)
logger.info(
'Overall test metrics: Accuracy = {:.4f}, precision = {:.4f}, recall = {:.4f}, '
'F1 score = {:.4f}'.format(np.mean(accuracies),
np.mean(precisions), np.mean(recalls),
np.mean(f1s)))
class Baseline:
def __init__(self, device, n_classes, training_mode, **kwargs):
self.lr = kwargs.get('lr', 3e-5)
self.device = device
self.training_mode = training_mode
self.model = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=n_classes,
max_length=kwargs.get('max_length'),
device=device)
logger.info('Loaded {} as model'.format(self.model.__class__.__name__))
self.loss_fn = nn.CrossEntropyLoss()
self.optimizer = AdamW(
[p for p in self.model.parameters() if p.requires_grad],
lr=self.lr)
def save_model(self, model_path):
checkpoint = self.model.state_dict()
torch.save(checkpoint, model_path)
def load_model(self, model_path):
checkpoint = torch.load(model_path)
self.model.load_state_dict(checkpoint)
def train(self, dataloader, n_epochs, log_freq):
self.model.train()
for epoch in range(n_epochs):
all_losses, all_predictions, all_labels = [], [], []
iter = 0
for text, labels in dataloader:
labels = torch.tensor(labels).to(self.device)
input_dict = self.model.encode_text(text)
output = self.model(input_dict)
loss = self.loss_fn(output, labels)
self.optimizer.zero_grad()
loss.backward()
self.optimizer.step()
loss = loss.item()
pred = models.utils.make_prediction(output.detach())
all_losses.append(loss)
all_predictions.extend(pred.tolist())
all_labels.extend(labels.tolist())
iter += 1
if iter % log_freq == 0:
acc, prec, rec, f1 = models.utils.calculate_metrics(
all_predictions, all_labels)
logger.info(
'Epoch {} metrics: Loss = {:.4f}, accuracy = {:.4f}, precision = {:.4f}, recall = {:.4f}, '
'F1 score = {:.4f}'.format(epoch + 1,
np.mean(all_losses), acc,
prec, rec, f1))
all_losses, all_predictions, all_labels = [], [], []
def evaluate(self, dataloader):
all_losses, all_predictions, all_labels = [], [], []
self.model.eval()
for text, labels in dataloader:
labels = torch.tensor(labels).to(self.device)
input_dict = self.model.encode_text(text)
with torch.no_grad():
output = self.model(input_dict)
loss = self.loss_fn(output, labels)
loss = loss.item()
pred = models.utils.make_prediction(output.detach())
all_losses.append(loss)
all_predictions.extend(pred.tolist())
all_labels.extend(labels.tolist())
acc, prec, rec, f1 = models.utils.calculate_metrics(
all_predictions, all_labels)
logger.info(
'Test metrics: Loss = {:.4f}, accuracy = {:.4f}, precision = {:.4f}, recall = {:.4f}, '
'F1 score = {:.4f}'.format(np.mean(all_losses), acc, prec, rec,
f1))
return acc, prec, rec, f1
def training(self, train_datasets, **kwargs):
n_epochs = kwargs.get('n_epochs', 1)
log_freq = kwargs.get('log_freq', 500)
mini_batch_size = kwargs.get('mini_batch_size')
if self.training_mode == 'sequential':
for train_dataset in train_datasets:
logger.info('Training on {}'.format(
train_dataset.__class__.__name__))
train_dataloader = data.DataLoader(
train_dataset,
batch_size=mini_batch_size,
shuffle=False,
collate_fn=datasets.utils.batch_encode)
self.train(dataloader=train_dataloader,
n_epochs=n_epochs,
log_freq=log_freq)
elif self.training_mode == 'multi_task':
train_dataset = data.ConcatDataset(train_datasets)
logger.info('Training multi-task model on all datasets')
train_dataloader = data.DataLoader(
train_dataset,
batch_size=mini_batch_size,
shuffle=True,
collate_fn=datasets.utils.batch_encode)
self.train(dataloader=train_dataloader,
n_epochs=n_epochs,
log_freq=log_freq)
else:
raise ValueError('Invalid training mode')
def testing(self, test_datasets, **kwargs):
mini_batch_size = kwargs.get('mini_batch_size')
accuracies, precisions, recalls, f1s = [], [], [], []
for test_dataset in test_datasets:
logger.info('Testing on {}'.format(
test_dataset.__class__.__name__))
test_dataloader = data.DataLoader(
test_dataset,
batch_size=mini_batch_size,
shuffle=False,
collate_fn=datasets.utils.batch_encode)
acc, prec, rec, f1 = self.evaluate(dataloader=test_dataloader)
accuracies.append(acc)
precisions.append(prec)
recalls.append(rec)
f1s.append(f1)
logger.info(
'Overall test metrics: Accuracy = {:.4f}, precision = {:.4f}, recall = {:.4f}, '
'F1 score = {:.4f}'.format(np.mean(accuracies),
np.mean(precisions), np.mean(recalls),
np.mean(f1s)))
class MAML:
def __init__(self, device, **kwargs):
self.inner_lr = kwargs.get('inner_lr')
self.meta_lr = kwargs.get('meta_lr')
self.write_prob = kwargs.get('write_prob')
self.replay_rate = kwargs.get('replay_rate')
self.replay_every = kwargs.get('replay_every')
self.device = device
self.pn = TransformerClsModel(model_name=kwargs.get('model'),
n_classes=1,
max_length=kwargs.get('max_length'),
device=device,
hebbian=kwargs.get('hebbian'))
logger.info('Loaded {} as PN'.format(self.pn.__class__.__name__))
meta_params = [p for p in self.pn.parameters() if p.requires_grad]
self.meta_optimizer = AdamW(meta_params, lr=self.meta_lr)
self.memory = ReplayMemory(write_prob=self.write_prob, tuple_size=3)
self.loss_fn = nn.BCEWithLogitsLoss()
inner_params = [p for p in self.pn.parameters() if p.requires_grad]
self.inner_optimizer = optim.SGD(inner_params, lr=self.inner_lr)
def save_model(self, model_path):
checkpoint = self.pn.state_dict()
torch.save(checkpoint, model_path)
def load_model(self, model_path):
checkpoint = torch.load(model_path)
self.pn.load_state_dict(checkpoint)
def evaluate(self, dataloader, updates, mini_batch_size):
self.pn.train()
support_set = []
for _ in range(updates):
text, label, candidates = self.memory.read_batch(
batch_size=mini_batch_size)
support_set.append((text, label, candidates))
with higher.innerloop_ctx(self.pn,
self.inner_optimizer,
copy_initial_weights=False,
track_higher_grads=False) as (fpn, diffopt):
# Inner loop
task_predictions, task_labels = [], []
support_loss = []
for text, label, candidates in support_set:
replicated_text, replicated_relations, ranking_label = datasets.utils.replicate_rel_data(
text, label, candidates)
input_dict = self.pn.encode_text(
list(zip(replicated_text, replicated_relations)))
output = fpn(input_dict)
targets = torch.tensor(ranking_label).float().unsqueeze(1).to(
self.device)
loss = self.loss_fn(output, targets)
diffopt.step(loss)
pred, true_labels = models.utils.make_rel_prediction(
output, ranking_label)
support_loss.append(loss.item())
task_predictions.extend(pred.tolist())
task_labels.extend(true_labels.tolist())
acc = models.utils.calculate_accuracy(task_predictions,
task_labels)
logger.info(
'Support set metrics: Loss = {:.4f}, accuracy = {:.4f}'.format(
np.mean(support_loss), acc))
all_losses, all_predictions, all_labels = [], [], []
for text, label, candidates in dataloader:
replicated_text, replicated_relations, ranking_label = datasets.utils.replicate_rel_data(
text, label, candidates)
with torch.no_grad():
input_dict = self.pn.encode_text(
list(zip(replicated_text, replicated_relations)))
output = fpn(input_dict)
targets = torch.tensor(ranking_label).float().unsqueeze(
1).to(self.device)
loss = self.loss_fn(output, targets)
loss = loss.item()
pred, true_labels = models.utils.make_rel_prediction(
output, ranking_label)
all_losses.append(loss)
all_predictions.extend(pred.tolist())
all_labels.extend(true_labels.tolist())
acc = models.utils.calculate_accuracy(all_predictions, all_labels)
logger.info('Test metrics: Loss = {:.4f}, accuracy = {:.4f}'.format(
np.mean(all_losses), acc))
return acc
def training(self, train_datasets, **kwargs):
updates = kwargs.get('updates')
mini_batch_size = kwargs.get('mini_batch_size')
if self.replay_rate != 0:
replay_batch_freq = self.replay_every // mini_batch_size
replay_freq = int(
math.ceil((replay_batch_freq + 1) / (updates + 1)))
replay_steps = int(self.replay_every * self.replay_rate /
mini_batch_size)
else:
replay_freq = 0
replay_steps = 0
logger.info('Replay frequency: {}'.format(replay_freq))
logger.info('Replay steps: {}'.format(replay_steps))
concat_dataset = data.ConcatDataset(train_datasets)
train_dataloader = iter(
data.DataLoader(concat_dataset,
batch_size=mini_batch_size,
shuffle=False,
collate_fn=datasets.utils.rel_encode))
episode_id = 0
while True:
self.inner_optimizer.zero_grad()
support_loss, support_acc = [], []
with higher.innerloop_ctx(self.pn,
self.inner_optimizer,
copy_initial_weights=False,
track_higher_grads=False) as (fpn,
diffopt):
# Inner loop
support_set = []
task_predictions, task_labels = [], []
for _ in range(updates):
try:
text, label, candidates = next(train_dataloader)
support_set.append((text, label, candidates))
except StopIteration:
logger.info(
'Terminating training as all the data is seen')
return
for text, label, candidates in support_set:
replicated_text, replicated_relations, ranking_label = datasets.utils.replicate_rel_data(
text, label, candidates)
input_dict = self.pn.encode_text(
list(zip(replicated_text, replicated_relations)))
output = fpn(input_dict)
targets = torch.tensor(ranking_label).float().unsqueeze(
1).to(self.device)
loss = self.loss_fn(output, targets)
diffopt.step(loss)
pred, true_labels = models.utils.make_rel_prediction(
output, ranking_label)
support_loss.append(loss.item())
task_predictions.extend(pred.tolist())
task_labels.extend(true_labels.tolist())
self.memory.write_batch(text, label, candidates)
acc = models.utils.calculate_accuracy(task_predictions,
task_labels)
logger.info(
'Episode {} support set: Loss = {:.4f}, accuracy = {:.4f}'.
format(episode_id + 1, np.mean(support_loss), acc))
# Outer loop
query_loss, query_acc = [], []
query_set = []
if self.replay_rate != 0 and (episode_id +
1) % replay_freq == 0:
for _ in range(replay_steps):
text, label, candidates = self.memory.read_batch(
batch_size=mini_batch_size)
query_set.append((text, label, candidates))
else:
try:
text, label, candidates = next(train_dataloader)
query_set.append((text, label, candidates))
self.memory.write_batch(text, label, candidates)
except StopIteration:
logger.info(
'Terminating training as all the data is seen')
return
for text, label, candidates in query_set:
replicated_text, replicated_relations, ranking_label = datasets.utils.replicate_rel_data(
text, label, candidates)
input_dict = self.pn.encode_text(
list(zip(replicated_text, replicated_relations)))
output = fpn(input_dict)
targets = torch.tensor(ranking_label).float().unsqueeze(
1).to(self.device)
loss = self.loss_fn(output, targets)
query_loss.append(loss.item())
pred, true_labels = models.utils.make_rel_prediction(
output, ranking_label)
acc = models.utils.calculate_accuracy(
pred.tolist(), true_labels.tolist())
query_acc.append(acc)
# PN meta gradients
pn_params = [
p for p in fpn.parameters() if p.requires_grad
]
meta_pn_grads = torch.autograd.grad(loss, pn_params)
pn_params = [
p for p in self.pn.parameters() if p.requires_grad
]
for param, meta_grad in zip(pn_params, meta_pn_grads):
if param.grad is not None:
param.grad += meta_grad.detach()
else:
param.grad = meta_grad.detach()
# Meta optimizer step
self.meta_optimizer.step()
self.meta_optimizer.zero_grad()
logger.info(
'Episode {} query set: Loss = {:.4f}, accuracy = {:.4f}'.
format(episode_id + 1, np.mean(query_loss),
np.mean(query_acc)))
episode_id += 1
def testing(self, test_dataset, **kwargs):
updates = kwargs.get('updates')
mini_batch_size = kwargs.get('mini_batch_size')
test_dataloader = data.DataLoader(test_dataset,
batch_size=mini_batch_size,
shuffle=False,
collate_fn=datasets.utils.rel_encode)
acc = self.evaluate(dataloader=test_dataloader,
updates=updates,
mini_batch_size=mini_batch_size)
logger.info('Overall test metrics: Accuracy = {:.4f}'.format(acc))
return acc
