def validate(model,
dev_data,
vocab_src,
vocab_tgt,
epoch,
config,
direction=None):
model.eval()
device = torch.device(
"cpu") if config["device"] == "cpu" else torch.device("cuda:0")
with torch.no_grad():
model_hypotheses = []
references = []
val_dl = DataLoader(dev_data,
batch_size=config["batch_size_eval"],
shuffle=False,
num_workers=4)
val_dl = BucketingParallelDataLoader(val_dl)
for sentences_x, sentences_y in val_dl:
if direction == None or direction == "xy":
x_in, _, x_mask, x_len = create_batch(sentences_x, vocab_src,
device)
x_mask = x_mask.unsqueeze(1)
else:
x_in, _, x_mask, x_len = create_batch(sentences_y, vocab_src,
device)
x_mask = x_mask.unsqueeze(1)
enc_output, enc_hidden = model.encode(x_in, x_len)
dec_hidden = model.init_decoder(enc_output, enc_hidden)
raw_hypothesis = beam_search(model.decoder, model.emb_tgt,
model.generate_tm, enc_output,
dec_hidden, x_mask, vocab_tgt.size(),
vocab_tgt[SOS_TOKEN],
vocab_tgt[EOS_TOKEN],
vocab_tgt[PAD_TOKEN], config)
hypothesis = batch_to_sentences(raw_hypothesis, vocab_tgt)
model_hypotheses += hypothesis.tolist()
if direction == None or direction == "xy":
references += sentences_y.tolist()
else:
references += sentences_x.tolist()
save_hypotheses(model_hypotheses, epoch, config)
model_hypotheses, references = clean_sentences(model_hypotheses,
references, config)
bleu = compute_bleu(model_hypotheses, references, epoch, config,
direction)
return bleu
def printKL(model, dev_data, vocab_src, vocab_tgt, config, direction=None):
model.eval()
with torch.no_grad():
model_hypotheses = []
references = []
device = torch.device(
"cpu") if config["device"] == "cpu" else torch.device("cuda:0")
val_dl = DataLoader(dev_data,
batch_size=config["batch_size_eval"],
shuffle=False,
num_workers=4)
# val_dl = BucketingParallelDataLoader(val_dl)
# print(len(dev_data))
kl = 0
z_list = []
for sentences_x, sentences_y in tqdm(val_dl):
if direction == None or direction == "xy":
sentences_x, sentences_y, sort_keys = sort_sentences(
sentences_x, sentences_y)
x_in, _, x_mask, x_len = create_batch(sentences_x, vocab_src,
device)
x_mask = x_mask.unsqueeze(1)
else:
sentences_y, sentences_x, sort_keys = sort_sentences(
sentences_y, sentences_x)
x_in, _, x_mask, x_len = create_batch(sentences_y, vocab_src,
device)
x_mask = x_mask.unsqueeze(1)
qz = model.inference(x_in, x_mask, x_len)
z = qz.mean
z_list.append(z)
enc_output, enc_hidden = model.encode(x_in, x_len, z)
dec_hidden = model.init_decoder(enc_output, enc_hidden, z)
pz = torch.distributions.Normal(loc=model.prior_loc,
scale=model.prior_scale).expand(
qz.mean.size())
kl_loss = torch.distributions.kl.kl_divergence(qz, pz)
kl_loss = kl_loss.sum(dim=1)
kl += kl_loss.sum(dim=0)
# kl_loss = kl_loss.sum(dim=0)
# print(kl_loss.shape)
kl /= len(dev_data)
print("KL_loss: ", kl)
z_tensor = torch.cat(z_list)
print(z_tensor.mean(dim=0))
print(z_tensor.var(dim=0))
def sample_from_posterior(model, sentences_x, vocab_src, vocab_tgt, config):
num_samples = 5
sentences_x = np.tile(sentences_x, 5)
device = torch.device(
"cpu") if config["device"] == "cpu" else torch.device("cuda:0")
x_in, _, x_mask, x_len = create_batch(sentences_x, vocab_src, device)
x_mask = x_mask.unsqueeze(1)
qz = model.inference(x_in, x_mask, x_len)
z = qz.sample()
enc_output, enc_hidden = model.encode(x_in, x_len, z)
dec_hidden = model.init_decoder(enc_output, enc_hidden, z)
y_samples = ancestral_sample(model.decoder,
model.emb_tgt,
model.generate_tm,
enc_output,
dec_hidden,
x_mask,
vocab_tgt[SOS_TOKEN],
vocab_tgt[EOS_TOKEN],
vocab_tgt[PAD_TOKEN],
config,
greedy=True,
z=z)
y_samples = batch_to_sentences(y_samples, vocab_tgt)
print("Sample translations from the approximate posterior")
for idx, y in enumerate(y_samples, 1):
print("{}: {}".format(idx, y))
def mono_train_fn(model_xy, model_yx, y_in, y_noisy_in, y_len, y_mask, y_out,
vocab_src, config, step):
device = torch.device(
"cpu") if config["device"] == "cpu" else torch.device("cuda:0")
with torch.no_grad():
enc_output, enc_final = model_yx.encode(y_in, y_len)
dec_hidden = model_yx.init_decoder(enc_output, enc_final)
if config["decoding_method"] == "beam_search":
x_samples = beam_search(model_yx.decoder,
model_yx.emb_tgt,
model_yx.generate_tm,
enc_output,
dec_hidden,
y_mask,
vocab_src.size(),
vocab_src[SOS_TOKEN],
vocab_src[EOS_TOKEN],
vocab_src[PAD_TOKEN],
config,
beam_width=config["decoding_beam_width"])
else:
greedy = False if config["decoding_method"] == "ancestral" else True
x_samples = ancestral_sample(model_yx.decoder,
model_yx.emb_tgt,
model_yx.generate_tm,
enc_output,
dec_hidden,
y_mask,
vocab_src[SOS_TOKEN],
vocab_src[EOS_TOKEN],
vocab_src[PAD_TOKEN],
config,
greedy=greedy)
x_samples = batch_to_sentences(x_samples, vocab_src)
x_in, x_out, x_mask, x_len = create_batch(x_samples, vocab_src, device)
x_mask = x_mask.unsqueeze(1)
logits = model_xy(x_in, x_mask, x_len, y_in)
loss = model_xy.loss(logits, y_out)
return loss
def validate(model,
dev_data,
vocab_src,
vocab_tgt,
epoch,
config,
direction=None):
model.eval()
device = torch.device(
"cpu") if config["device"] == "cpu" else torch.device("cuda:0")
with torch.no_grad():
model_hypotheses = []
references = []
val_dl = DataLoader(dev_data,
batch_size=config["batch_size_eval"],
shuffle=False,
num_workers=2)
val_dl = BucketingParallelDataLoader(val_dl)
val_kl = 0
for sentences_x, sentences_y in val_dl:
if direction == None or direction == "xy":
x_in, _, x_mask, x_len = create_batch(sentences_x, vocab_src,
device)
x_mask = x_mask.unsqueeze(1)
else:
x_in, _, x_mask, x_len = create_batch(sentences_y, vocab_src,
device)
x_mask = x_mask.unsqueeze(1)
qz = model.inference(x_in, x_mask, x_len)
z = qz.mean
pz = torch.distributions.Normal(loc=model.prior_loc,
scale=model.prior_scale).expand(
qz.mean.size())
kl_loss = torch.distributions.kl.kl_divergence(qz, pz)
kl_loss = kl_loss.sum(dim=1)
val_kl += kl_loss.sum(dim=0)
enc_output, enc_hidden = model.encode(x_in, x_len, z)
dec_hidden = model.init_decoder(enc_output, enc_hidden, z)
raw_hypothesis = beam_search(model.decoder, model.emb_tgt,
model.generate_tm, enc_output,
dec_hidden, x_mask, vocab_tgt.size(),
vocab_tgt[SOS_TOKEN],
vocab_tgt[EOS_TOKEN],
vocab_tgt[PAD_TOKEN], config, z)
hypothesis = batch_to_sentences(raw_hypothesis, vocab_tgt)
model_hypotheses += hypothesis.tolist()
if direction == None or direction == "xy":
references += sentences_y.tolist()
else:
references += sentences_x.tolist()
val_kl /= len(dev_data)
save_hypotheses(model_hypotheses, epoch, config, direction)
model_hypotheses, references = clean_sentences(model_hypotheses,
references, config)
bleu = compute_bleu(model_hypotheses,
references,
epoch,
config,
direction,
kl=val_kl)
return bleu
def main():
config = setup_config()
config["dev_prefix"] = "comparable"
vocab_src, vocab_tgt = load_vocabularies(config)
_, dev_data, _ = load_data(config,
vocab_src=vocab_src,
vocab_tgt=vocab_tgt)
model, _, validate_fn = create_model(vocab_src, vocab_tgt, config)
model.to(torch.device(config["device"]))
checkpoint_path = "{}/cond_nmt_de-en_run_7/checkpoints/cond_nmt_de-en_run_7".format(
config["out_dir"])
state = torch.load(checkpoint_path)
model.load_state_dict(state['state_dict'])
model.eval()
device = torch.device(
"cpu") if config["device"] == "cpu" else torch.device("cuda:0")
with torch.no_grad():
model_hypotheses = []
references = []
val_dl = DataLoader(dev_data,
batch_size=config["batch_size_eval"],
shuffle=False,
num_workers=4)
# val_dl = BucketingParallelDataLoader(val_dl)
for sentences_x, sentences_y in tqdm(val_dl):
sentences_x = np.array(sentences_x)
seq_len = np.array([len(s.split()) for s in sentences_x])
sort_keys = np.argsort(-seq_len)
sentences_x = sentences_x[sort_keys]
# #
sentences_y = np.array(sentences_y)
x_in, _, x_mask, x_len = create_batch(sentences_x, vocab_src,
device)
x_mask = x_mask.unsqueeze(1)
if config["model_type"] == "aevnmt":
qz = model.inference(x_in, x_mask, x_len)
z = qz.mean
enc_output, enc_hidden = model.encode(x_in, x_len, z)
dec_hidden = model.init_decoder(enc_output, enc_hidden, z)
raw_hypothesis = beam_search(model.decoder, model.emb_tgt,
model.generate_tm, enc_output,
dec_hidden, x_mask,
vocab_tgt.size(),
vocab_tgt[SOS_TOKEN],
vocab_tgt[EOS_TOKEN],
vocab_tgt[PAD_TOKEN], config)
else:
enc_output, enc_hidden = model.encode(x_in, x_len)
dec_hidden = model.decoder.initialize(enc_output, enc_hidden)
raw_hypothesis = beam_search(model.decoder, model.emb_tgt,
model.generate_tm, enc_output,
dec_hidden, x_mask,
vocab_tgt.size(),
vocab_tgt[SOS_TOKEN],
vocab_tgt[EOS_TOKEN],
vocab_tgt[PAD_TOKEN], config)
hypothesis = batch_to_sentences(raw_hypothesis, vocab_tgt)
inverse_sort_keys = np.argsort(sort_keys)
model_hypotheses += hypothesis[inverse_sort_keys].tolist()
references += sentences_y.tolist()
save_hypotheses(model_hypotheses, 0, config, None)
model_hypotheses, references = clean_sentences(model_hypotheses,
references, config)
bleu = sacrebleu.raw_corpus_bleu(model_hypotheses, [references]).score
print(bleu)
def main():
config = setup_config()
config["dev_prefix"] = "comparable"
vocab_src, vocab_tgt = load_vocabularies(config)
_, dev_data, _ = load_data(config,
vocab_src=vocab_src,
vocab_tgt=vocab_tgt)
# _, dev_data, vocab_src, vocab_tgt = load_dataset_joey(config)
model, _, validate_fn = create_model(vocab_src, vocab_tgt, config)
model.to(torch.device(config["device"]))
checkpoint_path = "{}/cond_nmt_new_de-en_run_2/checkpoints/cond_nmt_new_de-en_run_2".format(
config["out_dir"])
state = torch.load(checkpoint_path)
model.load_state_dict(state['state_dict'])
model.eval()
device = torch.device(
"cpu") if config["device"] == "cpu" else torch.device("cuda:0")
with torch.no_grad():
model_hypotheses = []
references = []
val_dl = DataLoader(dev_data,
batch_size=config["batch_size_eval"],
shuffle=False,
num_workers=4)
val_dl = BucketingParallelDataLoader(val_dl)
for sentences_x, sentences_y in tqdm(val_dl):
x_in, _, x_mask, x_len = create_batch(sentences_x, vocab_src,
device)
x_mask = x_mask.unsqueeze(1)
if config["model_type"] == "aevnmt":
qz = model.inference(x_in, x_mask)
z = qz.mean
enc_output, enc_hidden = model.encode(x_in, z)
dec_hidden = model.init_decoder(enc_output, enc_hidden, z)
raw_hypothesis = beam_search(model.decoder, model.emb_tgt,
model.generate_tm, enc_output,
dec_hidden, x_mask,
vocab_tgt.size(),
vocab_tgt[SOS_TOKEN],
vocab_tgt[EOS_TOKEN],
vocab_tgt[PAD_TOKEN], config)
else:
enc_output, enc_hidden = model.encode(x_in)
dec_hidden = model.decoder.initialize(enc_output, enc_hidden)
raw_hypothesis = beam_search(model.decoder, model.emb_tgt,
model.generate, enc_output,
dec_hidden, x_mask,
vocab_tgt.size(),
vocab_tgt[SOS_TOKEN],
vocab_tgt[EOS_TOKEN],
vocab_tgt[PAD_TOKEN], config)
hypothesis = batch_to_sentences(raw_hypothesis, vocab_tgt)
model_hypotheses += hypothesis.tolist()
references += sentences_y.tolist()
save_hypotheses(model_hypotheses, 0, config, None)
def evaluate(model, dev_data, vocab_src, vocab_tgt, config, direction=None):
model.eval()
with torch.no_grad():
model_hypotheses = []
references = []
device = torch.device(
"cpu") if config["device"] == "cpu" else torch.device("cuda:0")
val_dl = DataLoader(dev_data,
batch_size=config["batch_size_eval"],
shuffle=False,
num_workers=4)
# val_dl = BucketingParallelDataLoader(val_dl)
for sentences_x, sentences_y in tqdm(val_dl):
if direction == None or direction == "xy":
sentences_x, sentences_y, sort_keys = sort_sentences(
sentences_x, sentences_y)
x_in, _, x_mask, x_len = create_batch(sentences_x, vocab_src,
device)
x_mask = x_mask.unsqueeze(1)
else:
sentences_y, sentences_x, sort_keys = sort_sentences(
sentences_y, sentences_x)
x_in, _, x_mask, x_len = create_batch(sentences_y, vocab_src,
device)
x_mask = x_mask.unsqueeze(1)
if config["model_type"] == "coaevnmt":
qz = model.inference(x_in, x_mask, x_len)
z = qz.mean
enc_output, enc_hidden = model.encode(x_in, x_len, z)
dec_hidden = model.init_decoder(enc_output, enc_hidden, z)
raw_hypothesis = beam_search(model.decoder,
model.emb_tgt,
model.generate_tm,
enc_output,
dec_hidden,
x_mask,
vocab_tgt.size(),
vocab_tgt[SOS_TOKEN],
vocab_tgt[EOS_TOKEN],
vocab_tgt[PAD_TOKEN],
config,
z=z)
elif config["model_type"] == "conmt":
enc_output, enc_hidden = model.encode(x_in, x_len)
dec_hidden = model.decoder.initialize(enc_output, enc_hidden)
raw_hypothesis = beam_search(model.decoder, model.emb_tgt,
model.generate_tm, enc_output,
dec_hidden, x_mask,
vocab_tgt.size(),
vocab_tgt[SOS_TOKEN],
vocab_tgt[EOS_TOKEN],
vocab_tgt[PAD_TOKEN], config)
hypothesis = batch_to_sentences(raw_hypothesis, vocab_tgt)
inverse_sort_keys = np.argsort(sort_keys)
model_hypotheses += hypothesis[inverse_sort_keys].tolist()
if direction == None or direction == "xy":
references += sentences_y.tolist()
else:
references += sentences_x.tolist()
model_hypotheses, references = clean_sentences(model_hypotheses,
references, config)
bleu = sacrebleu.raw_corpus_bleu(model_hypotheses, [references]).score
print(bleu)
