在当今数字化的时代,分析用户评论中的情绪倾向对于相识产物、服务的口碑等方面有着重要意义。而基于强盛的预训练语言模子如 Bert 来进行评论情绪分析,可以或许取得较好的结果。 在本次项目中,我们将展示如何利用 Python 语言联合transformers库,借助 Bert 模子实现对给定评论数据集的情绪分类任务。
一、数据集说明
数据集可以在Aitsuio平台下载,下载链接,格式如下:
每个数据有评论内容和后面的情绪分类,我们所要做的就是根据评论内容进行分类。
下载数据集后,可以得到拥有三个差别的数据集文件,分别是train.txt、dev.txt和test.txt,它们各自负担差别的脚色。train.txt用于训练模子,dev.txt作为开辟集(验证集)在训练过程中帮助我们评估模子在未见过的数据上的体现,进而辅助调整模子的超参数等,test.txt则用于最终测试模子的泛化能力。
- content: 酒店还是非常的不错,我预定的是套间,服务非常好,随叫随到,结帐非常快。顺便提一句,这个酒店三楼是一个高级KTV,里面的服务小姐非常的漂亮,有机会去看看。
- idtype: 2
2.1 导包
起首,我们需要确保相关依靠库已经安装好,像transformers库用于方便地加载和利用 Bert 模子,torch库作为深度学习的基础框架(如果有 GPU 支持还能加快训练过程),以及datasets库辅助我们加载和处理数据集。如果未安装,直接pip安装即可。
- from transformers import BertTokenizer, BertForSequenceClassification
- from datasets import load_dataset
- import torch
- from torch.utils.data import DataLoader
- import numpy as np
所用到的模子是bert-base-chinese,可以在huggingface或者魔塔社区下载,如果不知道如何下载可以看我之前这篇博客,复制对应的地址即可。LLM/深度学习Linux常用指令与代码(进阶)
2.3 数据集加载
为了加载这些数据,需要自定义了一个名为CommentDataset的数据集类,它继承自torch.utils.data.Dataset,这个类负责将文本数据和对应的标签进行整合,方便后续被数据加载器(DataLoader)利用。
在具体的数据加载过程中,分别读取三个文件中的每一行数据,按照空格分割出评论内容和对应的情绪标签(示例中假设标签是整数情势,比如 0 代表负面情绪,1 代表正面情绪等),然后利用 Bert 的tokenizer对文本进行编码,将文本转化为模子可以或许担当的输入格式(包括添加input_ids、attention_mask等),最终分别创建出对应的训练集、开辟集和测试集的Dataset对象以及相应的DataLoader用于按批次加载数据。数据集加载代码如下:
- # 自定义数据集类,继承自torch.utils.data.Dataset
- class CommentDataset(torch.utils.data.Dataset):
- def __init__(self, encodings, labels):
- self.encodings = encodings
- self.labels = labels
- def __getitem__(self, idx):
- item = {key: torch.tensor(val[idx]) for key, val in self.encodings.items()}
- item['labels'] = torch.tensor(self.labels[idx])
- return item
- def __len__(self):
- return len(self.labels)
- # 加载训练集数据
- train_data = []
- train_labels = []
- with open('Dataset/train.txt', 'r', encoding='utf-8') as f:
- for line in f.readlines():
- text, label = line.split('\t')
- train_data.append(text)
- train_labels.append(int(label))
- # 对训练集进行编码
- tokenizer = BertTokenizer.from_pretrained('/root/model/bert-base-chinese')
- train_encodings = tokenizer(train_data, truncation=True, padding=True)
- train_dataset = CommentDataset(train_encodings, train_labels)
- train_loader = DataLoader(train_dataset, batch_size=8, shuffle=True)
- # 加载开发集数据
- dev_data = []
- dev_labels = []
- with open('Dataset/dev.txt', 'r', encoding='utf-8') as f:
- for line in f.readlines():
- text, label = line.split('\t')
- dev_data.append(text)
- dev_labels.append(int(label))
- # 对开发集进行编码
- dev_encodings = tokenizer(dev_data, truncation=True, padding=True)
- dev_dataset = CommentDataset(dev_encodings, dev_labels)
- dev_loader = DataLoader(dev_dataset, batch_size=8)
- # 加载测试集数据
- test_data = []
- test_labels = []
- with open('Dataset/test.txt', 'r', encoding='utf-8') as f:
- for line in f.readlines():
- text, label = line.split('\t')
- test_data.append(text)
- test_labels.append(int(label))
- # 对测试集进行编码
- test_encodings = tokenizer(test_data, truncation=True, padding=True)
- test_dataset = CommentDataset(test_encodings, test_labels)
- test_loader = DataLoader(test_dataset, batch_size=8)
利用BertForSequenceClassification一行下令即可加载模子。
- # 加载预训练的Bert模型用于序列分类,这里假设是二分类(0和1代表不同情感倾向),可以根据实际调整num_labels
- model = BertForSequenceClassification.from_pretrained('/root/model/bert-base-chinese', num_labels=len(idset))
接下来定义一个train函数,一个val函数,一个test函数,分别对应三个文件,然后就可以开始训练和测试啦!
- # 训练函数
- def train():
- device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
- model.to(device)
- optimizer = torch.optim.AdamW(model.parameters(), lr=1e-5)
- epochs = 3 # 可以根据实际调整训练轮数
- for epoch in range(epochs):
- model.train()
- for batch in train_loader:
- input_ids = batch['input_ids'].to(device)
- attention_mask = batch['attention_mask'].to(device)
- labels = batch['labels'].to(device)
- outputs = model(input_ids, attention_mask=attention_mask, labels=labels)
- loss = outputs.loss
- loss.backward()
- optimizer.step()
- optimizer.zero_grad()
- print(f'Epoch {epoch + 1} completed')
- # 在开发集上验证
- validate()
- # 验证函数(在开发集上查看模型表现辅助调参)
- def validate():
- device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
- model.eval()
- correct = 0
- total = 0
- with torch.no_grad():
- for batch in dev_loader:
- input_ids = batch['input_ids'].to(device)
- attention_mask = batch['attention_mask'].to(device)
- labels = batch['labels'].to(device)
- outputs = model(input_ids, attention_mask=attention_mask)
- _, predicted = torch.max(outputs.logits, dim=1)
- total += labels.size(0)
- correct += (predicted == labels).sum().item()
- print(f'Validation Accuracy: {correct / total}')
- # 评估函数
- def evaluate():
- device = torch.device('cuda' if torch.cuda.is_available() else 'cpu')
- model.eval()
- correct = 0
- total = 0
- with torch.no_grad():
- for batch in test_loader:
- input_ids = batch['input_ids'].to(device)
- attention_mask = batch['attention_mask'].to(device)
- labels = batch['labels'].to(device)
- outputs = model(input_ids, attention_mask=attention_mask)
- _, predicted = torch.max(outputs.logits, dim=1)
- total += labels.size(0)
- correct += (predicted == labels).sum().item()
- print(f'Test Accuracy: {correct / total}')
- train()
- evaluate()
可以看到,在test上有94%的精确率,还是非常不错的!
- Epoch 1 completed
- Validation Accuracy: 0.9435662345874171
- Epoch 2 completed
- Validation Accuracy: 0.9521024343977237
- Epoch 3 completed
- Validation Accuracy: 0.9524185899462535
- Test Accuracy: 0.9485416172634574
完整代码如下,需要的小伙伴可以自己获取!
- with open('Dataset/train.txt', 'r', encoding='utf-8') as f: train_data = f.read()with open('Dataset/dev.txt', 'r', encoding='utf-8') as f: eval_data = f.read() train_data = train_data.split('\n')eval_data = eval_data.split('\n')idset = set()for data in train_data: idset.add(data.split('\t')[-1])for data in eval_data: idset.add(data.split('\t')[-1])from transformers import BertTokenizer, BertForSequenceClassification
- from datasets import load_dataset
- import torch
- from torch.utils.data import DataLoader
- import numpy as np
- # 自定义数据集类,继承自torch.utils.data.Dataset
- class CommentDataset(torch.utils.data.Dataset):
- def __init__(self, encodings, labels):
- self.encodings = encodings
- self.labels = labels
- def __getitem__(self, idx):
- item = {key: torch.tensor(val[idx]) for key, val in self.encodings.items()}
- item['labels'] = torch.tensor(self.labels[idx])
- return item
- def __len__(self):
- return len(self.labels)
- # 加载训练集数据
- train_data = []
- train_labels = []
- with open('Dataset/train.txt', 'r', encoding='utf-8') as f:
- for line in f.readlines():
- text, label = line.split('\t')
- train_data.append(text)
- train_labels.append(int(label))
- # 对训练集进行编码
- tokenizer = BertTokenizer.from_pretrained('/root/model/bert-base-chinese')
- train_encodings = tokenizer(train_data, truncation=True, padding=True)
- train_dataset = CommentDataset(train_encodings, train_labels)
- train_loader = DataLoader(train_dataset, batch_size=8, shuffle=True)
- # 加载开发集数据
- dev_data = []
- dev_labels = []
- with open('Dataset/dev.txt', 'r', encoding='utf-8') as f:
- for line in f.readlines():
- text, label = line.split('\t')
- dev_data.append(text)
- dev_labels.append(int(label))
- # 对开发集进行编码
- dev_encodings = tokenizer(dev_data, truncation=True, padding=True)
- dev_dataset = CommentDataset(dev_encodings, dev_labels)
- dev_loader = DataLoader(dev_dataset, batch_size=8)
- # 加载测试集数据
- test_data = []
- test_labels = []
- with open('Dataset/test.txt', 'r', encoding='utf-8') as f:
- for line in f.readlines():
- text, label = line.split('\t')
- test_data.append(text)
- test_labels.append(int(label))
- # 对测试集进行编码
- test_encodings = tokenizer(test_data, truncation=True, padding=True)
- test_dataset = CommentDataset(test_encodings, test_labels)
- test_loader = DataLoader(test_dataset, batch_size=8)
- # 加载预训练的Bert模型用于序列分类,这里假设是二分类(0和1代表不同情感倾向),可以根据实际调整num_labels
- model = BertForSequenceClassification.from_pretrained('/root/model/bert-base-chinese', num_labels=len(idset))
- # 训练函数def train(): device = torch.device('cuda' if torch.cuda.is_available() else 'cpu') model.to(device) optimizer = torch.optim.AdamW(model.parameters(), lr=1e-5) epochs = 3 # 可以根据实际调整训练轮数 for epoch in range(epochs): model.train() for batch in train_loader: input_ids = batch['input_ids'].to(device) attention_mask = batch['attention_mask'].to(device) labels = batch['labels'].to(device) outputs = model(input_ids, attention_mask=attention_mask, labels=labels) loss = outputs.loss loss.backward() optimizer.step() optimizer.zero_grad() print(f'Epoch {epoch + 1} completed') # 在开辟集上验证 validate()# 验证函数(在开辟集上查看模子体现辅助调参)def validate(): device = torch.device('cuda' if torch.cuda.is_available() else 'cpu') model.eval() correct = 0 total = 0 with torch.no_grad(): for batch in dev_loader: input_ids = batch['input_ids'].to(device) attention_mask = batch['attention_mask'].to(device) labels = batch['labels'].to(device) outputs = model(input_ids, attention_mask=attention_mask) _, predicted = torch.max(outputs.logits, dim=1) total += labels.size(0) correct += (predicted == labels).sum().item() print(f'Validation Accuracy: {correct / total}')# 评估函数def evaluate(): device = torch.device('cuda' if torch.cuda.is_available() else 'cpu') model.eval() correct = 0 total = 0 with torch.no_grad(): for batch in test_loader: input_ids = batch['input_ids'].to(device) attention_mask = batch['attention_mask'].to(device) labels = batch['labels'].to(device) outputs = model(input_ids, attention_mask=attention_mask) _, predicted = torch.max(outputs.logits, dim=1) total += labels.size(0) correct += (predicted == labels).sum().item() print(f'Test Accuracy: {correct / total}')if __name__ == "__main__": train() evaluate()
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