def train(data, test, m, gamma): """ 该函数主要作用: 定义网络;定义数据,定义损失函数和优化器,计算重要指标,开始训练(训练网络,计算在测试集上的指标) 主要需要调整的参数: m 与 gamma :return: """ learnRate = 0.0001 lam = 0.00005 dim = 64 iter_ = 50 init_st = 0.01 m = m gamma = gamma batch_size = 100 n = 1000 k = 5 # 计算numUser, numItem, numTag dataload = DataSet(data, test, True) num_user, num_item, num_tag = dataload.calc_number_of_dimensions() predict_user_weight, item_weight = dataload.weight_to_vector(num_user, num_item, num_tag) # model = AttentionTAPITF(int(num_user), int(num_item), int(num_tag), dim, init_st, m, gamma, predict_user_weight, item_weight,ini_embeddings, True, 'tag', 'TAMLP').cuda() model = AttentionTAPITF(int(num_user), int(num_item), int(num_tag), dim, init_st, m, gamma, predict_user_weight, item_weight, ini_embeddings, True, 'tag', 'GMF').cuda() # model = AttentionTAPITF(int(num_user), int(num_item), int(num_tag), dim, init_st, m, gamma, predict_user_weight, item_weight, False, True, 'tag', 'TAMLP').cuda() # torch.save(model.state_dict(), 'attention_initial_params') # 对每个正样本进行负采样 loss_function = SinglePITF_Loss().cuda() opti = optim.SGD(model.parameters(), lr=learnRate, weight_decay=lam) # opti = optim.Adam(model.parameters(), lr=learnRate, weight_decay=lam) opti.zero_grad() # 每个epoch中的sample包含一个正样本和j个负样本 best_result = 0 # best_result_state = model.state_dict() # best_file = open('Attention_best_params.txt', 'a') # all_data = dataload.get_sequential(num_tag, m, 10, True) for epoch in range(iter_): # file_ = open('AttentionTureParam.txt', 'a') all_data = [] all_data = dataload.get_sequential(num_tag, m, 10, True) all_data = all_data[:, :8 + m] losses = [] print(datetime.datetime.now().strftime('%Y-%m-%d %H:%M:%S')) for i, batch in enumerate(dataload.get_batch(all_data, batch_size)): # print(batch) # input_ = dataload.draw_negative_sample(num_tag, sample, True) r = model(torch.LongTensor(batch).cuda()) opti.zero_grad() # print(model.embedding.userVecs.weight) loss = loss_function(r) # print(loss) # print(loss) loss.backward() opti.step() losses.append(loss.data) if i % n == 0: print("[%02d/%d] [%03d/%d] mean_loss : %0.2f" % ( epoch, iter_, i, len(all_data) / batch_size, np.mean(losses))) losses = [] precision = 0 recall = 0 count = 0 mrr = 0 recommend_count = 0 ndcg = 0 validaTagSet = dataload.validaTagSet for u in validaTagSet.keys(): for i in validaTagSet[u].keys(): number = 0 tags = validaTagSet[u][i] tagsNum = len(tags) if u in dataload.userShortMemory.keys(): x_t = torch.LongTensor([u, i] + list(dataload.userShortMemory[u][:m])).cuda() else: x_t = torch.LongTensor([u, i] + list(np.zeros(m))).cuda() x_t = x_t.unsqueeze(0) y_pre = model.predict_top_k(x_t, k) # print(y_pre) for tag in y_pre: if int(tag) in tags: number += 1 precision = precision + float(number / k) recall = recall + float(number / tagsNum) count += 1 mrr = mrr + mrr_rank_score(list(y_pre), list(tags)) # print(ndcg_score(np.array(y_pre), list(tags))) ndcg = ndcg + ndcg_score(np.array(y_pre), list(tags), k) recommend_count += tagsNum precision = precision / count recall = recall / count mrr = mrr / recommend_count ndcg = ndcg / count if precision == 0 and recall == 0: f_score = 0 else: f_score = 2 * (precision * recall) / (precision + recall) print("Precisions: " + str(precision)) print("Recall: " + str(recall)) print("F1: " + str(f_score)) print("MRR: " + str(mrr)) print("NDCG: " + str(ndcg)) # 将模型最好时的效果保存下来 if f_score > best_result: best_result = f_score # best_result_state = model.state_dict() print("best result: " + str(best_result)) print("==================================")
def train(data, test): """ 该函数主要作用: 定义网络;定义数据,定义损失函数和优化器,计算重要指标,开始训练(训练网络,计算在测试集上的指标) 主要需要调整的参数: m 与 gamma :return: """ learnRate = 0.05 lam = 0.00005 dim = 64 iter_ = 100 init_st = 0.01 m = 5 gamma = 0.5 batch_size = 100 n = 1000 # 计算numUser, numItem, numTag dataload = DataSet(data, test, True) num_user, num_item, num_tag = dataload.calc_number_of_dimensions() model = AttentionPITF(num_user, num_item, num_tag, dim, init_st, m, gamma).cuda() torch.save(model.state_dict(), 'attention_initial_params') # 对每个正样本进行负采样 loss_function = SinglePITF_Loss().cuda() opti = optim.SGD(model.parameters(), lr=learnRate, weight_decay=lam) opti.zero_grad() # 每个epoch中的sample包含一个正样本和j个负样本 best_result = 0 best_result_state = model.state_dict() for epoch in range(iter_): all_data = dataload.get_sequential(num_tag, m, 100) all_data = all_data[:, :4 + m] losses = [] print(datetime.datetime.now().strftime('%Y-%m-%d %H:%M:%S')) for i, batch in enumerate(dataload.get_batch(all_data, batch_size)): # print(batch) # input_ = dataload.draw_negative_sample(num_tag, sample, True) r = model(torch.LongTensor(batch).cuda()) opti.zero_grad() # print(model.embedding.userVecs.weight) loss = loss_function(r) # print(loss) loss.backward() opti.step() losses.append(loss.data) if i % n == 0: print("[%02d/%d] [%03d/%d] mean_loss : %0.2f" % (epoch, iter_, i, len(all_data) / batch_size, np.mean(losses))) losses = [] precision = 0 recall = 0 count = 0 validaTagSet = dataload.validaTagSet validaTimeList = dataload.validaUserTimeList for u in validaTagSet.keys(): for i in validaTagSet[u].keys(): number = 0 tags = validaTagSet[u][i] tagsNum = len(tags) x_t = torch.LongTensor( [u, i] + list(dataload.userShortMemory[u][:m])).cuda() x_t = x_t.unsqueeze(0) y_pre = model.predict_top_k(x_t) for tag in y_pre[0]: if int(tag) in tags: number += 1 precision = precision + float(number / 5) recall = recall + float(number / tagsNum) count += 1 precision = precision / count recall = recall / count if precision == 0 and recall == 0: f_score = 0 else: f_score = 2 * (precision * recall) / (precision + recall) print("Precisions: " + str(precision)) print("Recall: " + str(recall)) print("F1: " + str(f_score)) # 将模型最好时的效果保存下来 if f_score > best_result: best_result = f_score best_result_state = model.state_dict() print("best result: " + str(best_result)) print("==================================") # torch.save(model, "net.pkl") torch.save(best_result_state, "attention_net_params.pkl")
def train(data, test): """ 该函数主要作用: 定义网络;定义数据,定义损失函数和优化器,计算重要指标,开始训练(训练网络,计算在测试集上的指标) :return: """ learnRate = 0.01 lam = 0.00005 dim = 64 iter_ = 100 init_st = 0.01 # 计算numUser, numItem, numTag dataload = DataSet(data, test) num_user, num_item, num_tag = dataload.calc_number_of_dimensions() model = NeuralPITF(num_user, num_item, num_tag, dim, init_st).cuda() # 对每个正样本进行负采样 loss_function = PITF_Loss().cuda() opti = optim.SGD(model.parameters(), lr=learnRate, weight_decay=lam) opti.zero_grad() # 每个epoch中的sample包含一个正样本和j个负样本 for epoch in range(iter_): losses = [] n = 0 for sample in data: n += 1 numNeg = 10 input_ = sample while numNeg > 0: numNeg -= 1 neg = dataload.draw_negative_sample(num_tag, input_) sample = Variable(torch.LongTensor(input_)).cuda() neg = Variable(torch.LongTensor(neg)).cuda() r_p = model(sample) r_n = model(neg) opti.zero_grad() # print(model.embedding.userVecs.weight) loss = loss_function(r_p, r_n) loss.backward() opti.step() losses.append(loss.data) if n % 1000 == 0: print("the loss of %s sample in %s iter is : " % (str(epoch), str(n)) + str(np.mean(losses))) precision = 0 recall = 0 count = 0 validaTagSet = dataload.validaTagSet for u in validaTagSet.keys(): for i in validaTagSet[u].keys(): number = 0 tags = validaTagSet[u][i] tagsNum = len(tags) y_pre = model.predict_top_k(u, i, 5) for tag in y_pre: if tag in tags: number += 1 precision = precision + float(number / 5) recall = recall + float(number / tagsNum) count += 1 precision = precision / count recall = recall / count if precision == 0 and recall == 0: f_score = 0 else: f_score = 2 * (precision * recall) / (precision + recall) print("Precisions: " + str(precision)) print("Recall: " + str(recall)) print("F1: " + str(f_score)) print("==================================")