device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
######################################################################
-
parser = argparse.ArgumentParser(description = 'My own GPT.')
parser.add_argument('--log_filename',
type = str, default = 'adam')
parser.add_argument('--learning_rate',
- type = float, default = 1e-4)
+ type = float, default = 1e-3)
+
+parser.add_argument('--learning_rate_end',
+ type = float, default = 1e-6)
parser.add_argument('--dim_model',
type = int, default = 512)
parser.add_argument('--dropout',
type = float, default = 0.1)
-parser.add_argument('--synthesis_sampling',
- action='store_true', default = True)
+parser.add_argument('--deterministic_synthesis',
+ action='store_true', default = False)
parser.add_argument('--no_checkpoint',
action='store_true', default = False)
######################################################################
def autoregression(
- model,
- nb_samples, nb_tokens_to_generate, starting_input = None,
+ model, batch_size,
+ nb_samples, nb_tokens_to_generate, primer = None,
device = torch.device('cpu')
):
results = torch.zeros(
dtype = torch.int64, device = device
)
- if starting_input is None:
+ if primer is None:
first = 0
else:
- first = starting_input.size(1)
- results = torch.cat((starting_input, results), 1)
+ first = primer.size(1)
+ results = torch.cat((primer, results), 1)
- for input in results.split(args.batch_size):
- for s in tqdm.tqdm(range(first, input.size(1)), desc = 'synth'):
+ for input in results.split(batch_size):
+ for s in range(first, input.size(1)):
output = model(input)
logits = output[:, s]
- if args.synthesis_sampling:
+ if args.deterministic_synthesis:
+ t_next = logits.argmax(1)
+ else:
dist = torch.distributions.categorical.Categorical(logits = logits)
t_next = dist.sample()
- else:
- t_next = logits.argmax(1)
input[:, s] = t_next
return results
def vocabulary_size(self):
pass
- def produce_results(self, n_epoch, model, nb_tokens = 50):
+ def produce_results(self, n_epoch, model):
pass
######################################################################
class TaskPicoCLVR(Task):
+ # Make a tensor from a list of strings
+ def tensorize(self, descr):
+ token_descr = [ s.strip().split(' ') for s in descr ]
+ l = max([ len(s) for s in token_descr ])
+ #token_descr = [ [ '<nul>' ] * (l - len(s)) + s for s in token_descr ]
+ token_descr = [ s + [ '<nul>' ] * (l - len(s)) for s in token_descr ]
+ id_descr = [ [ self.token2id[u] for u in s ] for s in token_descr ]
+ return torch.tensor(id_descr, device = self.device)
+
+ def trim(self, x, token = '<nul>'):
+ n = self.token2id[token]
+ i = (1 - (F.pad(x, (1, 1), value = n) == n).min(0).values.long()).cumsum(0)
+ a, b = (i == 0).nonzero().max(), (i == i.max()).nonzero().min()
+ return x[:, a:b]
+
def __init__(self, batch_size,
height, width, nb_colors = 5,
device = torch.device('cpu')):
def generate_descr(nb):
- descr = picoclvr.generate(
+ return picoclvr.generate(
nb,
height = self.height, width = self.width,
nb_colors = nb_colors
)
- descr = [ s.strip().split(' ') for s in descr ]
- l = max([ len(s) for s in descr ])
- descr = [ s + [ '<unk>' ] * (l - len(s)) for s in descr ]
-
- return descr
-
self.height = height
self.width = width
self.batch_size = batch_size
self.device = device
nb = args.data_size if args.data_size > 0 else 250000
+ log_string(f'generating {nb} samples (can take some time)')
self.train_descr = generate_descr((nb * 4) // 5)
self.test_descr = generate_descr((nb * 1) // 5)
# Build the tokenizer
- tokens = set()
+ tokens = { '<nul>' }
for d in [ self.train_descr, self.test_descr ]:
for s in d:
- for t in s: tokens.add(t)
+ for t in s.strip().split(' '): tokens.add(t)
self.token2id = dict([ (t, n) for n, t in enumerate(tokens) ])
self.id2token = dict([ (n, t) for n, t in enumerate(tokens) ])
- t = [ [ self.token2id[u] for u in s ] for s in self.train_descr ]
- self.train_input = torch.tensor(t, device = self.device)
- t = [ [ self.token2id[u] for u in s ] for s in self.test_descr ]
- self.test_input = torch.tensor(t, device = self.device)
+ # Tokenize the train and test sets
+ self.train_input = self.tensorize(self.train_descr)
+ self.test_input = self.tensorize(self.test_descr)
def batches(self, split = 'train'):
assert split in { 'train', 'test' }
- if split == 'train':
- for batch in tqdm.tqdm(self.train_input.split(self.batch_size), desc = f'epoch-{split}'):
- yield batch
- else:
- for batch in tqdm.tqdm(self.test_input.split(self.batch_size), desc = f'epoch-{split}'):
- yield batch
+ input = self.train_input if split == 'train' else self.test_input
+ for batch in tqdm.tqdm(input.split(self.batch_size), desc = f'epoch-{split}'):
+ yield self.trim(batch)
def vocabulary_size(self):
return len(self.token2id)
- def generate(self, primer, model, nb_tokens):
- t_primer = primer.strip().split(' ')
- t_generated = [ ]
+ def test_model(self, n_epoch, model, primers_descr, nb_per_primer=1, generate_images=False):
+ nb_tokens_to_generate = self.height * self.width + 3
+ result_descr = [ ]
- for j in range(nb_tokens):
- t = [ [ self.token2id[u] for u in t_primer + t_generated ] ]
- input = torch.tensor(t, device = self.device)
- input = F.pad(input, (0, 1)) # Add the next token, the one to predict
- output = model(input)
- logits = output[0, -1]
- if args.synthesis_sampling:
- dist = torch.distributions.categorical.Categorical(logits = logits)
- t_next = dist.sample()
- else:
- t_next = logits.argmax()
- t_generated.append(self.id2token[t_next.item()])
-
- return ' '.join(t_primer + t_generated)
-
- def produce_results(self, n_epoch, model, nb_tokens = None):
- if nb_tokens is None:
- nb_tokens = self.height * self.width + 3
- descr = [ ]
- nb_per_primer = 8
-
- for primer in [
- 'red above green <sep> green top <sep> blue right of red <img>',
- 'there is red <sep> there is yellow <sep> there is blue <img>',
- 'red below yellow <sep> yellow below green <sep> green below blue <sep> red right <sep> yellow left <sep> green right <sep> blue left <img>',
- 'green bottom <sep> yellow bottom <sep> green left of blue <sep> yellow right of blue <sep> blue top <img>',
- ]:
-
- for k in range(nb_per_primer):
- descr.append(self.generate(primer, model, nb_tokens))
-
- img = [ picoclvr.descr2img(d, height = self.height, width = self.width) for d in descr ]
- img = torch.cat(img, 0)
- image_name = f'result_picoclvr_{n_epoch:04d}.png'
- torchvision.utils.save_image(
- img / 255.,
- image_name, nrow = nb_per_primer, pad_value = 0.8
+ for primer_descr in primers_descr:
+
+ results = autoregression(
+ model,
+ self.batch_size,
+ nb_samples = nb_per_primer,
+ nb_tokens_to_generate = nb_tokens_to_generate,
+ primer = self.tensorize([ primer_descr ]).expand(nb_per_primer, -1),
+ device = self.device
+ )
+
+ l = [ ' '.join([ self.id2token[t.item()] for t in r ]) for r in results ]
+ result_descr += l
+
+ np = picoclvr.nb_properties(
+ result_descr,
+ height = self.height, width = self.width
)
- log_string(f'wrote {image_name}')
- nb_missing = sum( [
- x[2] for x in picoclvr.nb_missing_properties(
- descr,
- height = self.height, width = self.width
+ nb_requested_properties, _, nb_missing_properties = zip(*np)
+
+ log_string(f'nb_requested_properties {sum(nb_requested_properties) / len(result_descr):.02f} nb_missing_properties {sum(nb_missing_properties) / len(result_descr):.02f}')
+
+ np=torch.tensor(np)
+ count=torch.empty(np[:,0].max()+1,np[:,2].max()+1,dtype=torch.int64)
+ for i in range(count.size(0)):
+ for j in range(count.size(1)):
+ count[i,j]=((np[:,0]==i).long()*(np[:,2]==j).long()).sum()
+
+ if generate_images:
+ img = [
+ picoclvr.descr2img(d, height = self.height, width = self.width)
+ for d in result_descr
+ ]
+
+ img = torch.cat(img, 0)
+ image_name = f'result_picoclvr_{n_epoch:04d}.png'
+ torchvision.utils.save_image(
+ img / 255.,
+ image_name, nrow = nb_per_primer, pad_value = 0.8
)
- ] )
+ log_string(f'wrote {image_name}')
+
+ return count
+
+ def produce_results(self, n_epoch, model):
+ primers_descr = [
+ 'red above green <sep> green top <sep> blue right of red <img>',
+ 'there is red <sep> there is yellow <sep> there is blue <img>',
+ 'red below yellow <sep> yellow below green <sep> green below blue <sep> red right <sep> yellow left <sep> green right <sep> blue left <img>',
+ 'green bottom <sep> yellow bottom <sep> green left of blue <sep> yellow right of blue <sep> blue top <img>',
+ ]
+
+ self.test_model(
+ n_epoch, model,
+ primers_descr,
+ nb_per_primer=8, generate_images=True
+ )
+
+ # FAR TOO SLOW!!!
- log_string(f'nb_missing {nb_missing / len(descr):.02f}')
+ # test_primers_descr=[ s.split('<img>')[0] for s in self.test_descr ]
+
+ # count=self.test_model(
+ # n_epoch, model,
+ # test_primers_descr,
+ # nb_per_primer=1, generate_images=False
+ # )
+
+ # with open(f'perf_{n_epoch:04d}.txt', 'w') as f:
+ # for i in range(count.size(0)):
+ # for j in range(count.size(1)):
+ # f.write(f'{count[i,j]}')
+ # f.write(" " if j<count.size(1)-1 else "\n")
######################################################################
self.vocab = torchtext.vocab.build_vocab_from_iterator(
yield_tokens(),
- specials = [ '<unk>', '<non>' ],
+ specials = [ '<unk>', '<nul>' ],
min_freq = self.min_freq
)
self.vocab.set_default_index(self.vocab[ '<unk>' ])
+ # makes a tensor from a list of list of tokens
def tensorize(self, s):
a = max(len(x) for x in s)
- return torch.tensor([ self.vocab(x + [ '<non>' ] * (a - len(x))) for x in s ])
+ return torch.tensor([ self.vocab(x + [ '<nul>' ] * (a - len(x))) for x in s ])
def yield_batches(self, ds):
s = [ ]
def vocabulary_size(self):
return len(self.vocab)
- def produce_results(self, n_epoch, model, nb_tokens = 50):
+ def produce_results(self, n_epoch, model):
+ nb_tokens = 50
file_name = f'result_wiki103_{n_epoch:04d}.txt'
with open(file_name, 'w') as outfile:
input = F.pad(input, (0, 1)) # Add the next token, the one to predict
output = model(input)
logits = output[0, -1]
- if args.synthesis_sampling:
+ if args.deterministic_synthesis:
+ t_next = logits.argmax()
+ else:
dist = torch.distributions.categorical.Categorical(logits = logits)
t_next = dist.sample()
- else:
- t_next = logits.argmax()
t_generated.append(self.vocab.lookup_token(t_next))
- if t_generated[-1] == '<non>': break
+ if t_generated[-1] == '<nul>': break
s = ' '.join(t_generated)
def vocabulary_size(self):
return 256
- def produce_results(self, n_epoch, model, nb_samples = 64):
- results = autoregression(model, nb_samples, 28 * 28, device = self.device)
+ def produce_results(self, n_epoch, model):
+ nb_samples = 64
+ results = autoregression(model, self.batch_size, nb_samples, 28 * 28, device = self.device)
image_name = f'result_mnist_{n_epoch:04d}.png'
torchvision.utils.save_image(1 - results.reshape(-1, 1, 28, 28) / 255.,
image_name, nrow = 16, pad_value = 0.8)
######################################################################
-if args.optim == 'sgd':
- optimizer = torch.optim.SGD(model.parameters(), lr = args.learning_rate)
-elif args.optim == 'adam':
- optimizer = torch.optim.Adam(model.parameters(), lr = args.learning_rate)
-elif args.optim == 'adamw':
- optimizer = torch.optim.AdamW(model.parameters(), lr = args.learning_rate)
-else:
- raise ValueError(f'Unknown optimizer {args.optim}.')
-
-######################################################################
-
nb_epochs_finished = 0
if args.no_checkpoint:
else:
try:
- checkpoint = torch.load(args.checkpoint_name, map_location = device)
+ checkpoint = torch.load(args.checkpoint_name)
nb_epochs_finished = checkpoint['nb_epochs_finished']
model.load_state_dict(checkpoint['model_state'])
- optimizer.load_state_dict(checkpoint['optimizer_state'])
+ torch.set_rng_state(checkpoint['rng_state'])
+ if torch.cuda.is_available():
+ torch.cuda.set_rng_state(checkpoint['cuda_rng_state'])
log_string(f'checkpoint loaded with {nb_epochs_finished} epochs finished.')
except FileNotFoundError:
for input in task.batches(split = 'train'):
token_count += F.one_hot(input, num_classes = task.vocabulary_size()).sum((0, 1))
token_probas = token_count / token_count.sum()
-h = -torch.xlogy(token_probas, token_probas).sum()
-train_set_perplexity = math.exp(h)
-log_string(f'train set perplexity {train_set_perplexity}')
+entropy = -torch.xlogy(token_probas, token_probas).sum()
+train_set_perplexity = math.exp(entropy)
-for k in range(nb_epochs_finished, nb_epochs):
+for n_epoch in range(nb_epochs_finished, nb_epochs):
+
+ if args.learning_rate_end < 0:
+ lr = args.learning_rate
+ else:
+ u = n_epoch / (nb_epochs - 1)
+ lr = math.exp((1 - u) * math.log(args.learning_rate) +
+ u * math.log(args.learning_rate_end))
+ log_string(f'learning_rate {lr}')
+
+ if args.optim == 'sgd':
+ optimizer = torch.optim.SGD(model.parameters(), lr = lr)
+ elif args.optim == 'adam':
+ optimizer = torch.optim.Adam(model.parameters(), lr = lr)
+ elif args.optim == 'adamw':
+ optimizer = torch.optim.AdamW(model.parameters(), lr = lr)
+ else:
+ raise ValueError(f'Unknown optimizer {args.optim}.')
model.train()
train_perplexity = math.exp(min(100, acc_train_loss/nb_train_samples))
test_perplexity = math.exp(min(100, acc_test_loss/nb_test_samples))
- log_string(f'perplexity {k} train {train_perplexity} test {test_perplexity}')
+ log_string(f'perplexity {n_epoch} train_set {train_set_perplexity} train_prediction {train_perplexity} test_prediction {test_perplexity}')
- task.produce_results(k, model)
+ task.produce_results(n_epoch, model)
checkpoint = {
- 'nb_epochs_finished': k + 1,
+ 'nb_epochs_finished': n_epoch + 1,
'model_state': model.state_dict(),
- 'optimizer_state': optimizer.state_dict()
+ 'rng_state': torch.get_rng_state(),
}
+ if torch.cuda.is_available():
+ checkpoint['cuda_rng_state'] = torch.cuda.get_rng_state()
+
torch.save(checkpoint, args.checkpoint_name)
######################################################################