input,
ar_mask,
seq_logproba,
- temperature=1.0,
- deterministic_synthesis=False,
+ temperature,
+ deterministic_synthesis,
):
to_generate = (ar_mask.sum(0) > 0).nonzero()
t_next = dist.sample()
all_n = torch.arange(t_next.size(0))
- seq_logproba += logits[all_n, t_next].sum(dim=-1)
+
+ seq_logproba += logits[all_n, t_next]
input[:, s] = ar_mask[:, s] * t_next + (1 - ar_mask[:, s]) * input[:, s]
).all()
return i_forward, i_backward
+ def non_trivial(self, quizzes):
+ quizzes = quizzes.clone()
+ n_forward = quizzes[quizzes[:, 0] == self.token_forward]
+ n_backward = quizzes[:, 0] == self.token_backward
+ backward = quizzes[n_backward]
+ quizzes[n_backward] = self.reverse_time(quizzes[n_backward])
+ return torch.logical_not(
+ self.problem.trivial_prompts_and_answers(
+ quizzes[:, 1 : 1 + self.prompt_len],
+ quizzes[:, 2 + self.prompt_len :],
+ )
+ )
+
def reverse_time(self, quizzes):
i_forward, i_backward = self.indices_forward_and_backward(quizzes)
self.prompt_len = None
self.answer_len = None
- self.train_w_quizzes = self.generate_token_sequences(nb_train_samples)
- self.reverse_random_half_in_place(self.train_w_quizzes)
- self.train_w_quizzes = self.train_w_quizzes.to(device)
+ # self.train_w_quizzes = self.generate_token_sequences(nb_train_samples)
+ # self.reverse_random_half_in_place(self.train_w_quizzes)
- self.test_w_quizzes = self.generate_token_sequences(nb_test_samples).to(device)
- self.reverse_random_half_in_place(self.test_w_quizzes)
- self.test_w_quizzes = self.test_w_quizzes.to(device)
+ # self.test_w_quizzes = self.generate_token_sequences(nb_test_samples).to(device)
+ # self.reverse_random_half_in_place(self.test_w_quizzes)
self.train_c_quizzes = []
self.test_c_quizzes = []
- if result_dir is not None:
- self.save_quizzes(
- result_dir,
- "culture_w_quizzes",
- self.train_w_quizzes[:72],
- )
+ # if result_dir is not None:
+ # self.save_quizzes(
+ # result_dir,
+ # "culture_w_quizzes",
+ # self.train_w_quizzes[:72],
+ # )
def save_quizzes(
self,
quizzes,
mistakes=None,
):
- quizzes = quizzes.clone()
+ quizzes = quizzes.clone().to("cpu")
n_forward = quizzes[quizzes[:, 0] == self.token_forward]
n_backward = quizzes[:, 0] == self.token_backward
backward = quizzes[n_backward]
predicted_answers = 1 - predicted_prompts
if mistakes is not None:
# 0/-1/+1 ~ not-to-predict / predicted wrong / predicted correct
- predicted_prompts *= mistakes
- predicted_answers *= mistakes
+ predicted_prompts *= mistakes.to("cpu")
+ predicted_answers *= mistakes.to("cpu")
else:
# 0/2 ~ not-to-predict / to predict
predicted_prompts *= 2
predicted_answers,
)
- def batches(self, split="train", desc=None):
+ def batches(self, model, split="train", desc=None):
assert split in {"train", "test"}
if split == "train":
- w_quizzes = self.train_w_quizzes
+ w_quizzes = model.train_w_quizzes
c_quizzes = self.train_c_quizzes
else:
- w_quizzes = self.test_w_quizzes
+ w_quizzes = model.test_w_quizzes
c_quizzes = self.test_c_quizzes
if len(c_quizzes) > 0:
backward_nb_total = correct[n_backward].size(0)
self.logger(
- f"forward_accuracy {log_prefix} {n_epoch} {model.id=} {forward_nb_correct} / {forward_nb_total}"
+ f"{log_prefix}_forward_accuracy {n_epoch} model {model.id} nb_correct {forward_nb_correct} / {forward_nb_total} ({forward_nb_correct*100/forward_nb_total} %)"
)
self.logger(
- f"backward_accuracy {log_prefix} {n_epoch} {model.id=} {backward_nb_correct} / {backward_nb_total}"
+ f"{log_prefix}_backward_accuracy {n_epoch} model {model.id} nb_correct {backward_nb_correct} / {backward_nb_total} ({backward_nb_correct*100/backward_nb_total} %)"
)
return result, correct
- compute_accuracy(self.train_w_quizzes[:nmax], log_prefix="train")
+ compute_accuracy(model.train_w_quizzes[:nmax], log_prefix="train")
test_result, test_correct = compute_accuracy(
- self.test_w_quizzes[:nmax], log_prefix="test"
+ model.test_w_quizzes[:nmax], log_prefix="test"
)
main_test_accuracy = test_correct.sum() / test_correct.size(0)
return main_test_accuracy
- def renew_w_quizzes(self, nb, for_train=True):
- input = self.train_w_quizzes if for_train else self.test_w_quizzes
+ def renew_w_quizzes(self, model, nb, for_train=True):
+ input = model.train_w_quizzes if for_train else model.test_w_quizzes
nb = min(nb, input.size(0))
input[:-nb] = input[nb:].clone()
fresh_w_quizzes = self.generate_token_sequences(nb)
else:
self.test_c_quizzes.append(new_c_quizzes)
+ def logproba_solution(self, models, c_quizzes):
+ logproba = c_quizzes.new_zeros(c_quizzes.size(0), len(models))
+
+ for model in models:
+ for input, l in zip(
+ c_quizzes.split(self.batch_size), logproba.split(self.batch_size)
+ ):
+ ar_mask = self.make_ar_mask(input)
+ output = model(mygpt.BracketedSequence(input)).x
+ ce = (
+ F.cross_entropy(output.transpose(1, 2), input, reduction="none")
+ * ar_mask
+ )
+ l[:, model.id] = -ce.sum(dim=-1)
+
+ return logproba
+
+ ###############################################################
+
def compute_correctness(
self,
c_quizzes,
nb_correct = 0
+ seq_logproba[...] = 0.0
+
for model in models_for_validation:
result = c_quizzes.clone()
- seq_logproba[...] = 0.0
-
ar_mask = self.make_ar_mask(result)
masked_inplace_autoregression(
def generate_quizzes(self, nb, model_for_generation, temperature=1.0):
c_quizzes = torch.empty(
- nb, self.train_w_quizzes.size(1), device=self.device, dtype=torch.int64
+ nb,
+ self.prompt_len + self.answer_len + 2,
+ device=self.device,
+ dtype=torch.int64,
)
seq_logproba = torch.zeros(nb, device=self.device)