import ffutils
import mygpt
-import sky, lang, quizz_machine
+import sky, grids, quiz_machine
# world quizzes vs. culture quizzes
parser.add_argument("--nb_test_samples", type=int, default=None)
-parser.add_argument("--learning_rate", type=float, default=1e-3)
+parser.add_argument("--learning_rate", type=float, default=5e-4)
########################################
parser.add_argument("--deterministic_synthesis", action="store_true", default=False)
-parser.add_argument("--problem", type=str, default="sky")
+parser.add_argument("--problem", type=str, default="grids")
parser.add_argument("--nb_gpts", type=int, default=5)
if args.dirty_debug:
args.accuracy_to_make_c_quizzes = 0.0
+ args.nb_gpts = 2
nb_new_c_quizzes_for_train = 100
nb_new_c_quizzes_for_test = 10
nb_iterations=args.sky_nb_iterations,
speed=args.sky_speed,
)
-elif args.problem == "lang":
- problem = lang.Lang(nb_iterations=2)
+ back_accuracy = False
+elif args.problem == "grids":
+ problem = grids.Grids(device=device)
+ back_accuracy = True
else:
raise ValueError
-quizz_machine = quizz_machine.QuizzMachine(
+quiz_machine = quiz_machine.QuizMachine(
problem=problem,
nb_train_samples=args.nb_train_samples,
nb_test_samples=args.nb_test_samples,
+ back_accuracy=back_accuracy,
batch_size=args.physical_batch_size,
result_dir=args.result_dir,
logger=log_string,
log_string(f"device {device}")
-vocabulary_size = quizz_machine.vocabulary_size()
+vocabulary_size = quiz_machine.vocabulary_size()
log_string(f"vocabulary_size {vocabulary_size}")
# Compute the entropy of the training tokens
token_count = 0
-for input in quizz_machine.batches(split="train", desc="train-entropy"):
- token_count += F.one_hot(input, num_classes=quizz_machine.vocabulary_size()).sum(
+for input in quiz_machine.batches(split="train", desc="train-entropy"):
+ token_count += F.one_hot(input, num_classes=quiz_machine.vocabulary_size()).sum(
(0, 1)
)
token_probas = token_count / token_count.sum()
nb_test, nb_in_train = 0, 0
for test_subset in subsets_as_tuples(
- quizz_machine.batches(split="test", desc="test-check"), 25000
+ quiz_machine.batches(split="test", desc="test-check"), 25000
):
in_train = set()
for train_subset in subsets_as_tuples(
- quizz_machine.batches(split="train", desc="train-check"), 25000
+ quiz_machine.batches(split="train", desc="train-check"), 25000
):
in_train.update(test_subset.intersection(train_subset))
nb_in_train += len(in_train)
##############################
-def one_epoch(model, quizz_machine):
+def one_epoch(model, quiz_machine):
optimizer = torch.optim.Adam(model.parameters(), lr=args.learning_rate)
model.train()
nb_train_samples, acc_train_loss = 0, 0.0
- for input in quizz_machine.batches(split="train"):
+ for input in quiz_machine.batches(split="train"):
input = input.to(device)
if nb_train_samples % args.batch_size == 0:
######################################################################
-def run_tests(model, quizz_machine, deterministic_synthesis):
+def run_tests(model, quiz_machine, deterministic_synthesis):
with torch.autograd.no_grad():
model.eval()
nb_test_samples, acc_test_loss = 0, 0.0
nb_samples_accumulated = 0
- for input in quizz_machine.batches(split="test"):
+ for input in quiz_machine.batches(split="test"):
input = input.to(device)
bs = model(mygpt.BracketedSequence(input))
log_string(f"test_perplexity {n_epoch} {test_perplexity}")
- model.main_test_accuracy = quizz_machine.produce_results(
+ model.main_test_accuracy = quiz_machine.produce_results(
n_epoch=n_epoch,
model=model,
result_dir=args.result_dir,
def create_c_quizzes(
models,
- quizz_machine,
+ quiz_machine,
nb_for_train=1000,
nb_for_test=100,
):
- recorded = []
+ quizzes_and_nb_correct_records = []
nb_to_create = nb_for_train + nb_for_test
)
file_name = os.path.join(args.result_dir, f"culture_c_quiz_{n_epoch:04d}_logp.dat")
+
with open(file_name, "w") as logp_file:
- while valid_c_quizzes(recorded, standard_validity).size(0) < nb_to_create:
+ while (
+ valid_c_quizzes(quizzes_and_nb_correct_records, standard_validity).size(0)
+ < nb_to_create
+ ):
# Select a model at random to generate the new quizzes
model_for_generation = models[torch.randint(len(models), (1,))]
- c_quizzes = quizz_machine.generate_quizzes(
+ c_quizzes = quiz_machine.generate_quizzes(
nb_to_create,
model_for_generation=model_for_generation,
temperature=args.generation_temperature,
)
- nb_correct, seq_logproba = quizz_machine.compute_correctness(
+ nb_correct, seq_logproba = quiz_machine.compute_correctness(
c_quizzes,
models,
bidirectional_validation=args.bidirectional_validation,
len(models) + 1, nb_correct.size(), device=c_quizzes.device
)
- recorded.append((c_quizzes, nb_correct))
+ quizzes_and_nb_correct_records.append((c_quizzes, nb_correct))
nv = F.one_hot(nb_correct, num_classes=len(models) + 1).sum(0)
nv = " ".join([str(x.item()) for x in nv])
- nb_validated = valid_c_quizzes(recorded, standard_validity).size(0)
+ nb_validated = valid_c_quizzes(
+ quizzes_and_nb_correct_records, standard_validity
+ ).size(0)
log_string(
f"keep c_quizzes model {model_for_generation.id} kept {nv} nb_accumulated {nb_validated} / {nb_to_create}"
# store the new c_quizzes which have been validated
- new_c_quizzes = valid_c_quizzes(recorded, standard_validity)
+ new_c_quizzes = valid_c_quizzes(quizzes_and_nb_correct_records, standard_validity)
+
+ quiz_machine.reverse_random_half_in_place(new_c_quizzes)
- quizz_machine.store_c_quizzes(new_c_quizzes[:nb_for_train], for_train=True)
- quizz_machine.store_c_quizzes(new_c_quizzes[nb_for_train:], for_train=False)
+ quiz_machine.store_c_quizzes(new_c_quizzes[:nb_for_train], for_train=True)
+ quiz_machine.store_c_quizzes(new_c_quizzes[nb_for_train:], for_train=False)
# save a bunch of images to investigate what quizzes with a
# certain nb of correct predictions look like
else ""
)
- q = valid_c_quizzes(recorded, criteria=lambda nb_correct: nb_correct == n)[:72]
+ q = valid_c_quizzes(
+ quizzes_and_nb_correct_records, criteria=lambda nb_correct: nb_correct == n
+ )[:72]
+
+ quiz_machine.reverse_random_half_in_place(q)
if q.size(0) > 0:
- quizz_machine.save_quizzes(
+ quiz_machine.save_quizzes(
args.result_dir, f"culture_c_quiz_{n_epoch:04d}_N{n}{s}", q
)
for n_epoch in range(args.nb_epochs):
log_string(f"--- epoch {n_epoch} ----------------------------------------")
+ cta = " ".join([f"{float(m.main_test_accuracy):.04f}" for m in models])
+ log_string(f"current_test_accuracies {cta}")
+
# Select, improve, and eval the worst model
weakest_model = min(models, key=lambda m: float(m.main_test_accuracy))
f"training model {weakest_model.id} main_test_accuracy {weakest_model.main_test_accuracy}"
)
- one_epoch(weakest_model, quizz_machine)
+ one_epoch(weakest_model, quiz_machine)
log_string(
- f"train_set_composition w_quizzes {quizz_machine.nb_batch_w_quizzes} c_quizzes {quizz_machine.nb_batch_c_quizzes}"
+ f"train_set_composition w_quizzes {quiz_machine.nb_batch_w_quizzes} c_quizzes {quiz_machine.nb_batch_c_quizzes}"
)
- run_tests(weakest_model, quizz_machine, deterministic_synthesis=False)
+ run_tests(weakest_model, quiz_machine, deterministic_synthesis=False)
log_string(
- f"test_set_composition w_quizzes {quizz_machine.nb_batch_w_quizzes} c_quizzes {quizz_machine.nb_batch_c_quizzes}"
+ f"test_set_composition w_quizzes {quiz_machine.nb_batch_w_quizzes} c_quizzes {quiz_machine.nb_batch_c_quizzes}"
)
- cta = " ".join([f"{float(m.main_test_accuracy):.04f}" for m in models])
- log_string(f"current_test_accuracies {cta}")
-
# Replace a fraction of the w_quizzes with fresh ones
- quizz_machine.renew_w_quizzes(args.nb_train_samples // args.nb_gpts)
+ quiz_machine.renew_w_quizzes(args.nb_train_samples // args.nb_gpts)
# If all the models are good enough, generate new quizzes and
# re-compute the test errors
if min([m.main_test_accuracy for m in models]) >= args.accuracy_to_make_c_quizzes:
create_c_quizzes(
models,
- quizz_machine,
+ quiz_machine,
nb_for_train=nb_new_c_quizzes_for_train,
nb_for_test=nb_new_c_quizzes_for_test,
)
for model in models:
- run_tests(model, quizz_machine, deterministic_synthesis=False)
+ run_tests(model, quiz_machine, deterministic_synthesis=False)
######################################################################