def run(): # load data ent2id = read_elements(os.path.join(config.data_path, "entities.dict")) rel2id = read_elements(os.path.join(config.data_path, "relations.dict")) ent_num = len(ent2id) rel_num = len(rel2id) train_triples = read_triples(os.path.join(config.data_path, "train.txt"), ent2id, rel2id) valid_triples = read_triples(os.path.join(config.data_path, "valid.txt"), ent2id, rel2id) test_triples = read_triples(os.path.join(config.data_path, "test.txt"), ent2id, rel2id) symmetry_test = read_triples( os.path.join(config.data_path, "symmetry_test.txt"), ent2id, rel2id) inversion_test = read_triples( os.path.join(config.data_path, "inversion_test.txt"), ent2id, rel2id) composition_test = read_triples( os.path.join(config.data_path, "composition_test.txt"), ent2id, rel2id) others_test = read_triples( os.path.join(config.data_path, "other_test.txt"), ent2id, rel2id) logging.info("#ent_num: %d" % ent_num) logging.info("#rel_num: %d" % rel_num) logging.info("#train triple num: %d" % len(train_triples)) logging.info("#valid triple num: %d" % len(valid_triples)) logging.info("#test triple num: %d" % len(test_triples)) logging.info("#Model: %s" % config.model) # 创建模型 kge_model = TransE(ent_num, rel_num) if config.model == "TransH": kge_model = TransH(ent_num, rel_num) elif config.model == "TransR": kge_model = SimpleTransR(ent_num, rel_num) elif config.model == "TransD": kge_model = TransD(ent_num, rel_num) elif config.model == "STransE": kge_model = STransE(ent_num, rel_num) elif config.model == "LineaRE": kge_model = LineaRE(ent_num, rel_num) elif config.model == "DistMult": kge_model = DistMult(ent_num, rel_num) elif config.model == "ComplEx": kge_model = ComplEx(ent_num, rel_num) elif config.model == "RotatE": kge_model = RotatE(ent_num, rel_num) elif config.model == "TransIJ": kge_model = TransIJ(ent_num, rel_num) kge_model = kge_model.cuda(torch.device("cuda:0")) logging.info("Model Parameter Configuration:") for name, param in kge_model.named_parameters(): logging.info("Parameter %s: %s, require_grad = %s" % (name, str(param.size()), str(param.requires_grad))) # 训练 train(model=kge_model, triples=(train_triples, valid_triples, test_triples, symmetry_test, inversion_test, composition_test, others_test), ent_num=ent_num)
def run(): set_logger() # load data ent_path = os.path.join(config.data_path, "entities.dict") rel_path = os.path.join(config.data_path, "relations.dict") ent2id = read_elements(ent_path) rel2id = read_elements(rel_path) ent_num = len(ent2id) rel_num = len(rel2id) train_triples = read_triples(os.path.join(config.data_path, "train.txt"), ent2id, rel2id) valid_triples = read_triples(os.path.join(config.data_path, "valid.txt"), ent2id, rel2id) test_triples = read_triples(os.path.join(config.data_path, "test.txt"), ent2id, rel2id) logging.info("#ent_num: %d" % ent_num) logging.info("#rel_num: %d" % rel_num) logging.info("#train triple num: %d" % len(train_triples)) logging.info("#valid triple num: %d" % len(valid_triples)) logging.info("#test triple num: %d" % len(test_triples)) logging.info("#Model: %s" % config.model) # 创建模型 kge_model = TransE(ent_num, rel_num) if config.model == "TransH": kge_model = TransH(ent_num, rel_num) elif config.model == "TransR": kge_model = TransR(ent_num, rel_num) elif config.model == "TransD": kge_model = TransD(ent_num, rel_num) elif config.model == "STransE": kge_model = STransE(ent_num, rel_num) elif config.model == "LineaRE": kge_model = LineaRE(ent_num, rel_num) elif config.model == "DistMult": kge_model = DistMult(ent_num, rel_num) elif config.model == "ComplEx": kge_model = ComplEx(ent_num, rel_num) elif config.model == "RotatE": kge_model = RotatE(ent_num, rel_num) if config.cuda: kge_model = kge_model.cuda() logging.info("Model Parameter Configuration:") for name, param in kge_model.named_parameters(): logging.info("Parameter %s: %s, require_grad = %s" % (name, str(param.size()), str(param.requires_grad))) # 训练 train(model=kge_model, triples=(train_triples, valid_triples, test_triples), ent_num=ent_num)
class Train: def __init__(self, data_name): self.dataset = get_dataset(data_name) self.n_entities = self.dataset.n_entities self.n_relations = self.dataset.n_relations def prepareData(self): print("Perpare dataloader") self.train = TrainDataset(self.dataset) self.trainloader = None self.valid = EvalDataset(self.dataset) self.validloader = DataLoader(self.valid, batch_size=self.valid.n_triples, shuffle=False) def prepareModel(self): print("Perpare model") self.model = TransE(self.n_entities, self.n_relations, embDim=100) if GPU: self.model.cuda() def saveModel(self): pickle.dump(self.model.get_emb_weights(), open('emb_weight.pkl', 'wb')) def fit(self): optim = torch.optim.Adam(self.model.parameters(), lr=LR) minLoss = float("inf") bestMR = float("inf") GlobalEpoch = 0 for seed in range(100): print(f"# Using seed: {seed}") self.train.regenerate_neg_samples(seed=seed) self.trainloader = DataLoader(self.train, batch_size=1024, shuffle=True, num_workers=4) for epoch in range(EPOCHS_PER_SEED): GlobalEpoch += 1 for sample in self.trainloader: if GPU: pos_triples = torch.LongTensor( sample['pos_triples']).cuda() neg_triples = torch.LongTensor( sample['neg_triples']).cuda() else: pos_triples = torch.LongTensor(sample['pos_triples']) neg_triples = torch.LongTensor(sample['neg_triples']) self.model.normal_emb() loss = self.model(pos_triples, neg_triples) if GPU: lossVal = loss.cpu().item() else: lossVal = loss.item() optim.zero_grad() loss.backward() optim.step() if minLoss > lossVal: minLoss = lossVal MR = Eval_MR(self.validloader, "L2", **self.model.get_emb_weights()) if MR < bestMR: bestMR = MR print('save embedding weight') self.saveModel() print( f"Epoch: {epoch + 1}, Total_Train: {GlobalEpoch}, Loss: {lossVal}, minLoss: {minLoss}," f"MR: {MR}, bestMR: {bestMR}") if GlobalEpoch % LR_DECAY_EPOCH == 0: adjust_learning_rate(optim, 0.96)
def main(): opts = get_train_args() print("load data ...") data = DataSet('data/modified_triples.txt') dataloader = DataLoader(data, shuffle=True, batch_size=opts.batch_size) print("load model ...") if opts.model_type == 'transe': model = TransE(opts, data.ent_tot, data.rel_tot) elif opts.model_type == "distmult": model = DistMult(opts, data.ent_tot, data.rel_tot) if opts.optimizer == 'Adam': optimizer = optim.Adam(model.parameters(), lr=opts.lr) elif opts.optimizer == 'SGD': optimizer = optim.SGD(model.parameters(), lr=opts.lr) model.cuda() model.relation_normalize() loss = torch.nn.MarginRankingLoss(margin=opts.margin) print("start training") for epoch in range(1, opts.epochs + 1): print("epoch : " + str(epoch)) model.train() epoch_start = time.time() epoch_loss = 0 tot = 0 cnt = 0 for i, batch_data in enumerate(dataloader): optimizer.zero_grad() batch_h, batch_r, batch_t, batch_n = batch_data batch_h = torch.LongTensor(batch_h).cuda() batch_r = torch.LongTensor(batch_r).cuda() batch_t = torch.LongTensor(batch_t).cuda() batch_n = torch.LongTensor(batch_n).cuda() pos_score, neg_score, dist = model.forward(batch_h, batch_r, batch_t, batch_n) pos_score = pos_score.cpu() neg_score = neg_score.cpu() dist = dist.cpu() train_loss = loss(pos_score, neg_score, torch.ones(pos_score.size(-1))) + dist train_loss.backward() optimizer.step() batch_loss = torch.sum(train_loss) epoch_loss += batch_loss batch_size = batch_h.size(0) tot += batch_size cnt += 1 print('\r{:>10} epoch {} progress {} loss: {}\n'.format( '', epoch, tot / data.__len__(), train_loss), end='') end = time.time() time_used = end - epoch_start epoch_loss /= cnt print('one epoch time: {} minutes'.format(time_used / 60)) print('{} epochs'.format(epoch)) print('epoch {} loss: {}'.format(epoch, epoch_loss)) if epoch % opts.save_step == 0: print("save model...") model.entity_normalize() torch.save(model.state_dict(), 'model.pt') print("save model...") model.entity_normalize() torch.save(model.state_dict(), 'model.pt') print("[Saving embeddings of whole entities & relations...]") save_embeddings(model, opts, data.id2ent, data.id2rel) print("[Embedding results are saved successfully.]")