######################################################################
-def generation_order(x, fixed_len):
+def generation_order(x, fixed_len=0):
if args.random_regression_order:
order = torch.rand(x.size(), device=x.device)
- order[:, :fixed_len] = torch.linspace(-2, -1, fixed_len, device=order.device)
+ order[:, :fixed_len] = torch.arange(-fixed_len, 0, device=x.device)
order = order.sort(1).indices
else:
order = (
return order
-def reorder(x, order, back=False): # x is NxTxD1x...xDk, order is NxT'
+def reorder(x, order, reverse=False): # x is NxTxD1x...xDk, order is NxT'
u = x.reshape(x.size()[:2] + (-1,))
order = order.unsqueeze(-1).expand(-1, -1, u.size(-1))
- if back:
- v = u.new(u.size())
- v.scatter_(1, order, u)
+ if reverse:
+ v = u.new(u.size()).scatter_(1, order, u)
else:
v = u.gather(1, order)
v = v.reshape(v.size()[:2] + x.size()[2:])
return reorder(x, order), order
+def eval_mygpt(model, input, mode="standard", fixed_len=0):
+ x, order = shuffle(input, fixed_len)
+ x = model(mygpt.BracketedSequence(x), mode=mode, order=order).x
+ return reorder(x, order, reverse=True)
+
+
######################################################################
# ar_mask is a Boolean matrix of same shape as input, with 1s on the
def masked_inplace_autoregression(model, batch_size, input, ar_mask, order=None):
- for input, ar_mask in zip(input.split(batch_size), ar_mask.split(batch_size)):
+ for input, ar_mask, order in zip(
+ input.split(batch_size), ar_mask.split(batch_size), order.split(batch_size)
+ ):
i = (ar_mask.sum(0) > 0).nonzero()
if i.min() > 0:
# Needed to initialize the model's cache
######################################################################
-def compute_perplexity(model, fixed_len, split="train"):
+def compute_perplexity(model, task, fixed_len, split="train"):
with torch.autograd.no_grad():
t = model.training
model.eval()
for input in task.batches(split=split):
input = input.to(device)
- x, order = shuffle(input, fixed_len)
- x = model(mygpt.BracketedSequence(x), order=order).x
- output = reorder(x, order, back=True)
+ output = eval_mygpt(model, input, fixed_len=fixed_len)
loss = F.cross_entropy(output.transpose(1, 2), input)
acc_loss += loss.item() * input.size(0)
nb_samples += input.size(0)
acc_train_loss, nb_train_samples = 0, 0
for mazes, policies in task.policy_batches(split="train"):
- x, order = shuffle(mazes, task.height * task.width)
- x = gpt(mygpt.BracketedSequence(x), mode=args.oneshot_input, order=order).x
- output_gpt = reorder(x, order, back=True)
+ output_gpt = eval_mygpt(
+ gpt, mazes, mode=args.oneshot_input, fixed_len=task.height * task.width
+ )
output = model(output_gpt)
loss = compute_loss(mazes, output, policies, task.height, task.width)
acc_test_loss, nb_test_samples = 0, 0
for mazes, policies in task.policy_batches(split="test"):
- x, order = shuffle(mazes, task.height * task.width)
- x = gpt(mygpt.BracketedSequence(x), mode=args.oneshot_input, order=order).x
- output_gpt = reorder(x, order, back=True)
+ output_gpt = eval_mygpt(
+ gpt, mazes, mode=args.oneshot_input, fixed_len=task.height * task.width
+ )
output = model(output_gpt)
loss = compute_loss(mazes, output, policies, task.height, task.width)
acc_test_loss += loss.item() * mazes.size(0)
# -------------------
mazes = task.test_input[:32, : task.height * task.width]
policies = task.test_policies[:32]
- x, order = shuffle(mazes, task.height * task.width)
- x = gpt(mygpt.BracketedSequence(x), mode=args.oneshot_input, order=order).x
- output_gpt = reorder(x, order, back=True)
+ output_gpt = eval_mygpt(
+ gpt, mazes, mode=args.oneshot_input, fixed_len=task.height * task.width
+ )
output = model(output_gpt)
if args.oneshot_output == "policy":
targets = policies.permute(0, 2, 1)
masked_inplace_autoregression(
model, self.batch_size, x, ar_mask, order=order
)
- result = reorder(x, order, back=True)
+ result = reorder(x, order, reverse=True)
mazes, paths = self.seq2map(result)
nb_correct += maze.path_correctness(mazes, paths).long().sum()
nb_total += mazes.size(0)
ar_mask = result.new_zeros(result.size())
ar_mask[:, self.height * self.width :] = 1
result *= 1 - ar_mask
- masked_inplace_autoregression(model, self.batch_size, result, ar_mask)
+ x, order = shuffle(result, self.height * self.width)
+ masked_inplace_autoregression(
+ model, self.batch_size, x, ar_mask, order=order
+ )
+ result = reorder(x, order, reverse=True)
mazes, paths = self.seq2map(input)
_, predicted_paths = self.seq2map(result)
if nb_epochs_finished >= args.nb_epochs:
n_epoch = nb_epochs_finished
train_perplexity = compute_perplexity(
- model, fixed_len=task.height * task.width, split="train"
+ model, task, fixed_len=task.height * task.width, split="train"
)
test_perplexity = compute_perplexity(
- model, fixed_len=task.height * task.width, split="test"
+ model, task, fixed_len=task.height * task.width, split="test"
)
log_string(
for input in task.batches(split="train"):
input = input.to(device)
- x, order = shuffle(input, task.height * task.width)
- x = model(mygpt.BracketedSequence(x), order=order).x
- output = reorder(x, order, back=True)
+ output = eval_mygpt(
+ model, input, mode=args.oneshot_input, fixed_len=task.height * task.width
+ )
loss = F.cross_entropy(output.transpose(1, 2), input)
acc_train_loss += loss.item() * input.size(0)
nb_train_samples += input.size(0)
train_perplexity = math.exp(min(100, acc_train_loss / nb_train_samples))
test_perplexity = compute_perplexity(
- model, fixed_len=task.height * task.width, split="test"
+ model, task, fixed_len=task.height * task.width, split="test"
)
log_string(