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面向初学者的深度学习课:
吴恩达《人人 AI》(特别通俗) https://www.zhihu.com/education/video-course/1556316449043668992
李沐的深度学习课 (稍微深一点) https://www.zhihu.com/education/video-course/1647604835598092705
在这个更广泛的定位上,已经有很多优秀的课程。本课程只针对大模型微调的知识基础展开。
订酒店机器人
[
{
"role": "user",
"content": "您好,我要找一家舒适型酒店住宿,然后希望酒店提供暖气与行李寄存。"
},
{
"role": "search",
"arguments": {
"facilities": [
"暖气",
"行李寄存"
],
"type": "舒适型"
}
},
{
"role": "return",
"records": [
{
"name": "北京香江戴斯酒店",
"type": "舒适型",
"address": "北京东城区南河沿大街南湾子胡同1号",
"subway": "天安门东地铁站B口",
"phone": "010-65127788",
"facilities": [
"酒店各处提供wifi",
"国际长途电话",
"吹风机",
"24小时热水",
"暖气",
"西式餐厅",
"中式餐厅",
"残疾人设施",
"会议室",
"无烟房",
"商务中心",
"早餐服务",
"接机服务",
"接待外宾",
"洗衣服务",
"行李寄存",
"租车",
"叫醒服务"
],
"price": 328.0,
"rating": 4.2,
"hotel_id": 10
}
]
},
{
"role": "assistant",
"content": "那推荐您北京香江戴斯酒店,符合您的全部住宿要求并且价格又比较合适的酒店。"
},
{
"role": "user",
"content": "这家酒店的价格是多少?"
},
{
"role": "assistant",
"content": "这家酒店的价格是每晚328.0元。"
},
{
"role": "user",
"content": "好的,那就预订北京香江戴斯酒店吧!"
},
{
"role": "assistant",
"content": "好的,祝您入住愉快!"
}
]
上手操作一个简单的例子:
安装依赖
# pip安装
pip install transformers # 安装最新的版本
pip install transformers == 4.30 # 安装指定版本
# conda安装
conda install -c huggingface transformers # 只4.0以后的版本
注意:
以下的代码,都不要在Jupyter笔记上直接运行,会死机!!
请下载左边的脚本`experiments/tiny/train.py`,在实验服务器上运行。
import datasets
from datasets import load_dataset
from transformers import AutoTokenizer, AutoModel
from transformers import AutoModelForCausalLM
from transformers import TrainingArguments, Seq2SeqTrainingArguments
from transformers import Trainer, Seq2SeqTrainer
import transformers
from transformers import DataCollatorWithPadding
from transformers import TextGenerationPipeline
import torch
import numpy as np
import os, re
from tqdm import tqdm
import torch.nn as nn
通过HuggingFace,可以指定数据集名称,运行时自动下载
# 数据集名称
DATASET_NAME = "rotten_tomatoes"
# 加载数据集
raw_datasets = load_dataset(DATASET_NAME)
# 训练集
raw_train_dataset = raw_datasets["train"]
# 验证集
raw_valid_dataset = raw_datasets["validation"]
通过HuggingFace,可以指定模型名称,运行时自动下载
# 模型名称
MODEL_NAME = "gpt2"
# 加载模型
model = AutoModelForCausalLM.from_pretrained(MODEL_NAME,trust_remote_code=True)
通过HuggingFace,可以指定模型名称,运行时自动下载对应Tokenizer
# 加载tokenizer
tokenizer = AutoTokenizer.from_pretrained(MODEL_NAME,trust_remote_code=True)
tokenizer.add_special_tokens({'pad_token': '[PAD]'})
tokenizer.pad_token_id = 0
# 其它相关公共变量赋值
# 设置随机种子:同个种子的随机序列可复现
transformers.set_seed(42)
# 标签集
named_labels = ['neg','pos']
# 标签转 token_id
label_ids = [
tokenizer(named_labels[i],add_special_tokens=False)["input_ids"][0]
for i in range(len(named_labels))
]
MAX_LEN=32 #最大序列长度(输入+输出)
DATA_BODY_KEY = "text" # 数据集中的输入字段名
DATA_LABEL_KEY = "label" #数据集中输出字段名
# 定义数据处理函数,把原始数据转成input_ids, attention_mask, labels
def process_fn(examples):
model_inputs = {
"input_ids": [],
"attention_mask": [],
"labels": [],
}
for i in range(len(examples[DATA_BODY_KEY])):
inputs = tokenizer(examples[DATA_BODY_KEY][i],add_special_tokens=False)
label = label_ids[examples[DATA_LABEL_KEY][i]]
input_ids = inputs["input_ids"] + [tokenizer.eos_token_id, label]
raw_len = len(input_ids)
input_len = len(inputs["input_ids"]) + 1
if raw_len >= MAX_LEN:
input_ids = input_ids[-MAX_LEN:]
attention_mask = [1] * MAX_LEN
labels = [-100]*(MAX_LEN - 1) + [label]
else:
input_ids = input_ids + [tokenizer.pad_token_id] * (MAX_LEN - raw_len)
attention_mask = [1] * raw_len + [0] * (MAX_LEN - raw_len)
labels = [-100]*input_len + [label] + [-100] * (MAX_LEN - raw_len)
model_inputs["input_ids"].append(input_ids)
model_inputs["attention_mask"].append(attention_mask)
model_inputs["labels"].append(labels)
return model_inputs
# 处理训练数据集
tokenized_train_dataset = raw_train_dataset.map(
process_fn,
batched=True,
remove_columns=raw_train_dataset.columns,
desc="Running tokenizer on train dataset",
)
# 处理验证数据集
tokenized_valid_dataset = raw_valid_dataset.map(
process_fn,
batched=True,
remove_columns=raw_valid_dataset.columns,
desc="Running tokenizer on validation dataset",
)
# 定义数据校准器(自动生成batch)
collater = DataCollatorWithPadding(
tokenizer=tokenizer, return_tensors="pt",
)
LR=2e-5 # 学习率
BATCH_SIZE=8 # Batch大小
INTERVAL=100 # 每多少步打一次 log / 做一次 eval
# 定义训练参数
training_args = TrainingArguments(
output_dir="./output", # checkpoint保存路径
evaluation_strategy="steps", # 按步数计算eval频率
overwrite_output_dir=True,
num_train_epochs=1, # 训练epoch数
per_device_train_batch_size=BATCH_SIZE, # 每张卡的batch大小
gradient_accumulation_steps=1, # 累加几个step做一次参数更新
per_device_eval_batch_size=BATCH_SIZE, # evaluation batch size
eval_steps=INTERVAL, # 每N步eval一次
logging_steps=INTERVAL, # 每N步log一次
save_steps=INTERVAL, # 每N步保存一个checkpoint
learning_rate=LR, # 学习率
)
# 节省显存
model.gradient_checkpointing_enable()
# 定义训练器
trainer = Trainer(
model=model, # 待训练模型
args=training_args, # 训练参数
data_collator=collater, # 数据校准器
train_dataset=tokenized_train_dataset, # 训练集
eval_dataset=tokenized_valid_dataset, # 验证集
# compute_metrics=compute_metric, # 计算自定义评估指标
)
# 开始训练
trainer.train()
划重点:
记住上面的流程,你就能跑通模型训练过程
理解下面的知识,你就能训练好模型效果
尝试: 用简单的数学语言表达概念
把它想象成一个方程:
每条数据就是一对儿 ,它们是常量
参数是未知数,是变量
就是表达式:我们不知道真实的公式是什么样的,所以假设了一个足够复杂的公式(比如,一个特定结构的神经网络)
这个求解这个方程(近似解)就是训练过程
通俗的讲: 训练,就是确定这组参数的取值
用数学(数值分析)方法找到使模型在训练集上表现足够好的一个值
表现足够好,就是说,对每个数据样本,使 的值尽可能接近
一个神经元:
把很多神经元连接起来,就成了神经网络:、、、...
这里的叫激活函数,有很多种形式
现今的大模型中常用的激活函数包括:ReLU、GELU、Swish
思考: 这里如果没有激活函数会怎样?
我们希望找到一组参数,使模型预测的输出与真实的输出,尽可能的接近
这里,我们(至少)需要两个要素:
回忆一下梯度的定义
从最简单的情况说起:梯度下降与凸问题
梯度决定了函数变化的方向,每次迭代更新我们会收敛到一个极值
其中,叫做学习率,它和梯度的模数共同决定了每步走多远
经验:
如果全量参数训练:条件允许的情况下,先尝试Batch Size大些
小参数量微调:Batch Size 大不一定就好,看稳定性
划重点:适当调整学习率(Learning Rate),避免陷入很差的局部解或者跳过了好的解
为了让训练过程更好的收敛,人们设计了很多更复杂的求解器
两个数值的差距,Mean Squared Error: (等价于欧式距离,见下文)
两个向量之间的(欧式)距离:
两个向量之间的夹角(余弦距离):
两个概率分布之间的差异,交叉熵: ——假设是概率分布 p,q 是离散的
这些损失函数也可以组合使用(在模型蒸馏的场景常见这种情况),例如,其中是一个预先定义的权重,也叫一个「超参」
思考: 你能找到这些损失函数和分类、聚类、回归问题之间的关系吗?
用 PyTorch 训练一个最简单的神经网络
数据集(MNIST)样例:
输入一张 28×28 的图像,输出标签 0--9
from __future__ import print_function
import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim
from torchvision import datasets, transforms
from torch.optim.lr_scheduler import StepLR
BATCH_SIZE = 64
TEST_BACTH_SIZE = 1000
EPOCHS = 15
LR = 0.01
SEED = 42
LOG_INTERVAL = 100
# 定义一个全连接网络
class FeedForwardNet(nn.Module):
def __init__(self):
super().__init__()
# 第一层784维输入、256维输出 -- 图像大小28×28=784
self.fc1 = nn.Linear(784, 256)
# 第二层256维输入、128维输出
self.fc2 = nn.Linear(256, 128)
# 第三层128维输入、64维输出
self.fc3 = nn.Linear(128, 64)
# 第四层64维输入、10维输出 -- 输出类别10类(0,1,...9)
self.fc4 = nn.Linear(64, 10)
# Dropout module with 0.2 drop probability
self.dropout = nn.Dropout(p=0.2)
def forward(self, x):
# 把输入展平成1D向量
x = x.view(x.shape[0], -1)
# 每层激活函数是ReLU,额外加dropout
x = self.dropout(F.relu(self.fc1(x)))
x = self.dropout(F.relu(self.fc2(x)))
x = self.dropout(F.relu(self.fc3(x)))
# 输出为10维概率分布
x = F.log_softmax(self.fc4(x), dim=1)
return x
# 训练过程
def train(model, loss_fn, device, train_loader, optimizer, epoch):
# 开启梯度计算
model.train()
for batch_idx, (data_input, true_label) in enumerate(train_loader):
# 从数据加载器读取一个batch
# 把数据上载到GPU(如有)
data_input, true_label = data_input.to(device), true_label.to(device)
# 求解器初始化(每个batch初始化一次)
optimizer.zero_grad()
# 正向传播:模型由输入预测输出
output = model(data_input)
# 计算loss
loss = loss_fn(output, true_label)
# 反向传播:计算当前batch的loss的梯度
loss.backward()
# 由求解器根据梯度更新模型参数
optimizer.step()
# 间隔性的输出当前batch的训练loss
if batch_idx % LOG_INTERVAL == 0:
print('Train Epoch: {} [{}/{} ({:.0f}%)]\tLoss: {:.6f}'.format(
epoch, batch_idx * len(data_input), len(train_loader.dataset),
100. * batch_idx / len(train_loader), loss.item()))
# 计算在测试集的准确率和loss
def test(model, loss_fn, device, test_loader):
model.eval()
test_loss = 0
correct = 0
with torch.no_grad():
for data, target in test_loader:
data, target = data.to(device), target.to(device)
output = model(data)
# sum up batch loss
test_loss += loss_fn(output, target, reduction='sum').item()
# get the index of the max log-probability
pred = output.argmax(dim=1, keepdim=True)
correct += pred.eq(target.view_as(pred)).sum().item()
test_loss /= len(test_loader.dataset)
print('\nTest set: Average loss: {:.4f}, Accuracy: {}/{} ({:.0f}%)\n'.format(
test_loss, correct, len(test_loader.dataset),
100. * correct / len(test_loader.dataset)))
def main():
# 检查是否有GPU
use_cuda = torch.cuda.is_available()
# 设置随机种子(以保证结果可复现)
torch.manual_seed(SEED)
# 训练设备(GPU或CPU)
device = torch.device("cuda" if use_cuda else "cpu")
# 设置batch size
train_kwargs = {'batch_size': BATCH_SIZE}
test_kwargs = {'batch_size': TEST_BACTH_SIZE}
if use_cuda:
cuda_kwargs = {'num_workers': 1,
'pin_memory': True,
'shuffle': True}
train_kwargs.update(cuda_kwargs)
test_kwargs.update(cuda_kwargs)
# 数据预处理(转tensor、数值归一化)
transform = transforms.Compose([
transforms.ToTensor(),
transforms.Normalize((0.1307,), (0.3081,))
])
# 自动下载MNIST数据集
dataset_train = datasets.MNIST('data', train=True, download=True,
transform=transform)
dataset_test = datasets.MNIST('data', train=False,
transform=transform)
# 定义数据加载器(自动对数据加载、多线程、随机化、划分batch、等等)
train_loader = torch.utils.data.DataLoader(dataset_train, **train_kwargs)
test_loader = torch.utils.data.DataLoader(dataset_test, **test_kwargs)
# 创建神经网络模型
model = FeedForwardNet().to(device)
# 指定求解器
optimizer = optim.SGD(model.parameters(), lr=LR)
# scheduler = StepLR(optimizer, step_size=1, gamma=0.9)
# 定义loss函数
# 注:nll 作用于 log_softmax 等价于交叉熵,感兴趣的同学可以自行推导
# https://blog.csdn.net/weixin_38145317/article/details/103288032
loss_fn = F.nll_loss
# 训练N个epoch
for epoch in range(1, EPOCHS + 1):
train(model, loss_fn, device, train_loader, optimizer, epoch)
test(model, loss_fn, device, test_loader)
# scheduler.step()
if __name__ == '__main__':
main()
/opt/conda/lib/python3.11/site-packages/tqdm/auto.py:21: TqdmWarning: IProgress not found. Please update jupyter and ipywidgets. See https://ipywidgets.readthedocs.io/en/stable/user_install.html
from .autonotebook import tqdm as notebook_tqdm
Train Epoch: 1 [0/60000 (0%)] Loss: 2.287443
Train Epoch: 1 [6400/60000 (11%)] Loss: 2.284967
Train Epoch: 1 [12800/60000 (21%)] Loss: 2.273498
Train Epoch: 1 [19200/60000 (32%)] Loss: 2.022655
Train Epoch: 1 [25600/60000 (43%)] Loss: 1.680803
Train Epoch: 1 [32000/60000 (53%)] Loss: 1.322924
Train Epoch: 1 [38400/60000 (64%)] Loss: 0.978875
Train Epoch: 1 [44800/60000 (75%)] Loss: 0.955985
Train Epoch: 1 [51200/60000 (85%)] Loss: 0.670422
Train Epoch: 1 [57600/60000 (96%)] Loss: 0.821590
Test set: Average loss: 0.5133, Accuracy: 8522/10000 (85%)
Train Epoch: 2 [0/60000 (0%)] Loss: 0.740346
Train Epoch: 2 [6400/60000 (11%)] Loss: 0.697988
Train Epoch: 2 [12800/60000 (21%)] Loss: 0.676830
Train Epoch: 2 [19200/60000 (32%)] Loss: 0.531716
Train Epoch: 2 [25600/60000 (43%)] Loss: 0.457828
Train Epoch: 2 [32000/60000 (53%)] Loss: 0.621303
Train Epoch: 2 [38400/60000 (64%)] Loss: 0.354285
Train Epoch: 2 [44800/60000 (75%)] Loss: 0.588098
Train Epoch: 2 [51200/60000 (85%)] Loss: 0.530143
Train Epoch: 2 [57600/60000 (96%)] Loss: 0.533157
Test set: Average loss: 0.3203, Accuracy: 9035/10000 (90%)
Train Epoch: 3 [0/60000 (0%)] Loss: 0.425095
Train Epoch: 3 [6400/60000 (11%)] Loss: 0.301024
Train Epoch: 3 [12800/60000 (21%)] Loss: 0.330063
Train Epoch: 3 [19200/60000 (32%)] Loss: 0.362905
Train Epoch: 3 [25600/60000 (43%)] Loss: 0.387243
Train Epoch: 3 [32000/60000 (53%)] Loss: 0.436325
Train Epoch: 3 [38400/60000 (64%)] Loss: 0.266472
Train Epoch: 3 [44800/60000 (75%)] Loss: 0.463275
Train Epoch: 3 [51200/60000 (85%)] Loss: 0.264305
Train Epoch: 3 [57600/60000 (96%)] Loss: 0.480805
Test set: Average loss: 0.2456, Accuracy: 9262/10000 (93%)
Train Epoch: 4 [0/60000 (0%)] Loss: 0.343381
Train Epoch: 4 [6400/60000 (11%)] Loss: 0.222288
Train Epoch: 4 [12800/60000 (21%)] Loss: 0.200421
Train Epoch: 4 [19200/60000 (32%)] Loss: 0.301372
Train Epoch: 4 [25600/60000 (43%)] Loss: 0.282800
Train Epoch: 4 [32000/60000 (53%)] Loss: 0.424678
Train Epoch: 4 [38400/60000 (64%)] Loss: 0.160868
Train Epoch: 4 [44800/60000 (75%)] Loss: 0.373828
Train Epoch: 4 [51200/60000 (85%)] Loss: 0.273351
Train Epoch: 4 [57600/60000 (96%)] Loss: 0.498258
Test set: Average loss: 0.2007, Accuracy: 9388/10000 (94%)
Train Epoch: 5 [0/60000 (0%)] Loss: 0.175644
Train Epoch: 5 [6400/60000 (11%)] Loss: 0.349571
Train Epoch: 5 [12800/60000 (21%)] Loss: 0.231020
Train Epoch: 5 [19200/60000 (32%)] Loss: 0.277835
Train Epoch: 5 [25600/60000 (43%)] Loss: 0.248639
Train Epoch: 5 [32000/60000 (53%)] Loss: 0.338623
Train Epoch: 5 [38400/60000 (64%)] Loss: 0.174397
Train Epoch: 5 [44800/60000 (75%)] Loss: 0.384121
Train Epoch: 5 [51200/60000 (85%)] Loss: 0.238978
Train Epoch: 5 [57600/60000 (96%)] Loss: 0.279425
Test set: Average loss: 0.1718, Accuracy: 9461/10000 (95%)
Train Epoch: 6 [0/60000 (0%)] Loss: 0.146129
Train Epoch: 6 [6400/60000 (11%)] Loss: 0.270161
Train Epoch: 6 [12800/60000 (21%)] Loss: 0.157764
Train Epoch: 6 [19200/60000 (32%)] Loss: 0.274829
Train Epoch: 6 [25600/60000 (43%)] Loss: 0.224544
Train Epoch: 6 [32000/60000 (53%)] Loss: 0.273076
Train Epoch: 6 [38400/60000 (64%)] Loss: 0.091917
Train Epoch: 6 [44800/60000 (75%)] Loss: 0.318671
Train Epoch: 6 [51200/60000 (85%)] Loss: 0.220927
Train Epoch: 6 [57600/60000 (96%)] Loss: 0.353987
Test set: Average loss: 0.1518, Accuracy: 9534/10000 (95%)
Train Epoch: 7 [0/60000 (0%)] Loss: 0.169520
Train Epoch: 7 [6400/60000 (11%)] Loss: 0.189826
Train Epoch: 7 [12800/60000 (21%)] Loss: 0.139019
Train Epoch: 7 [19200/60000 (32%)] Loss: 0.231475
Train Epoch: 7 [25600/60000 (43%)] Loss: 0.213273
Train Epoch: 7 [32000/60000 (53%)] Loss: 0.326085
Train Epoch: 7 [38400/60000 (64%)] Loss: 0.124614
Train Epoch: 7 [44800/60000 (75%)] Loss: 0.314796
Train Epoch: 7 [51200/60000 (85%)] Loss: 0.173023
Train Epoch: 7 [57600/60000 (96%)] Loss: 0.272714
Test set: Average loss: 0.1353, Accuracy: 9580/10000 (96%)
Train Epoch: 8 [0/60000 (0%)] Loss: 0.139128
Train Epoch: 8 [6400/60000 (11%)] Loss: 0.144777
Train Epoch: 8 [12800/60000 (21%)] Loss: 0.102367
Train Epoch: 8 [19200/60000 (32%)] Loss: 0.192136
Train Epoch: 8 [25600/60000 (43%)] Loss: 0.141218
Train Epoch: 8 [32000/60000 (53%)] Loss: 0.234929
Train Epoch: 8 [38400/60000 (64%)] Loss: 0.103180
Train Epoch: 8 [44800/60000 (75%)] Loss: 0.320878
Train Epoch: 8 [51200/60000 (85%)] Loss: 0.156626
Train Epoch: 8 [57600/60000 (96%)] Loss: 0.349143
Test set: Average loss: 0.1235, Accuracy: 9614/10000 (96%)
Train Epoch: 9 [0/60000 (0%)] Loss: 0.136772
Train Epoch: 9 [6400/60000 (11%)] Loss: 0.161713
Train Epoch: 9 [12800/60000 (21%)] Loss: 0.130365
Train Epoch: 9 [19200/60000 (32%)] Loss: 0.111859
Train Epoch: 9 [25600/60000 (43%)] Loss: 0.216221
Train Epoch: 9 [32000/60000 (53%)] Loss: 0.166046
Train Epoch: 9 [38400/60000 (64%)] Loss: 0.077858
Train Epoch: 9 [44800/60000 (75%)] Loss: 0.263344
Train Epoch: 9 [51200/60000 (85%)] Loss: 0.153452
Train Epoch: 9 [57600/60000 (96%)] Loss: 0.358510
Test set: Average loss: 0.1135, Accuracy: 9640/10000 (96%)
Train Epoch: 10 [0/60000 (0%)] Loss: 0.091045
Train Epoch: 10 [6400/60000 (11%)] Loss: 0.185156
Train Epoch: 10 [12800/60000 (21%)] Loss: 0.098523
Train Epoch: 10 [19200/60000 (32%)] Loss: 0.213850
Train Epoch: 10 [25600/60000 (43%)] Loss: 0.112603
Train Epoch: 10 [32000/60000 (53%)] Loss: 0.254803
Train Epoch: 10 [38400/60000 (64%)] Loss: 0.074294
Train Epoch: 10 [44800/60000 (75%)] Loss: 0.200418
Train Epoch: 10 [51200/60000 (85%)] Loss: 0.162135
Train Epoch: 10 [57600/60000 (96%)] Loss: 0.328646
Test set: Average loss: 0.1075, Accuracy: 9678/10000 (97%)
Train Epoch: 11 [0/60000 (0%)] Loss: 0.110555
Train Epoch: 11 [6400/60000 (11%)] Loss: 0.185066
Train Epoch: 11 [12800/60000 (21%)] Loss: 0.154370
Train Epoch: 11 [19200/60000 (32%)] Loss: 0.187331
Train Epoch: 11 [25600/60000 (43%)] Loss: 0.103054
Train Epoch: 11 [32000/60000 (53%)] Loss: 0.097087
Train Epoch: 11 [38400/60000 (64%)] Loss: 0.094759
Train Epoch: 11 [44800/60000 (75%)] Loss: 0.254946
Train Epoch: 11 [51200/60000 (85%)] Loss: 0.163511
Train Epoch: 11 [57600/60000 (96%)] Loss: 0.375709
Test set: Average loss: 0.1001, Accuracy: 9702/10000 (97%)
Train Epoch: 12 [0/60000 (0%)] Loss: 0.085661
Train Epoch: 12 [6400/60000 (11%)] Loss: 0.267067
Train Epoch: 12 [12800/60000 (21%)] Loss: 0.162384
Train Epoch: 12 [19200/60000 (32%)] Loss: 0.181441
Train Epoch: 12 [25600/60000 (43%)] Loss: 0.109263
Train Epoch: 12 [32000/60000 (53%)] Loss: 0.194257
Train Epoch: 12 [38400/60000 (64%)] Loss: 0.065200
Train Epoch: 12 [44800/60000 (75%)] Loss: 0.288888
Train Epoch: 12 [51200/60000 (85%)] Loss: 0.167924
Train Epoch: 12 [57600/60000 (96%)] Loss: 0.311067
Test set: Average loss: 0.0956, Accuracy: 9722/10000 (97%)
Train Epoch: 13 [0/60000 (0%)] Loss: 0.093631
Train Epoch: 13 [6400/60000 (11%)] Loss: 0.079958
Train Epoch: 13 [12800/60000 (21%)] Loss: 0.143489
Train Epoch: 13 [19200/60000 (32%)] Loss: 0.087933
Train Epoch: 13 [25600/60000 (43%)] Loss: 0.094754
Train Epoch: 13 [32000/60000 (53%)] Loss: 0.132700
Train Epoch: 13 [38400/60000 (64%)] Loss: 0.060542
Train Epoch: 13 [44800/60000 (75%)] Loss: 0.212000
Train Epoch: 13 [51200/60000 (85%)] Loss: 0.092904
Train Epoch: 13 [57600/60000 (96%)] Loss: 0.243191
Test set: Average loss: 0.0912, Accuracy: 9739/10000 (97%)
Train Epoch: 14 [0/60000 (0%)] Loss: 0.036139
Train Epoch: 14 [6400/60000 (11%)] Loss: 0.185927
Train Epoch: 14 [12800/60000 (21%)] Loss: 0.094324
Train Epoch: 14 [19200/60000 (32%)] Loss: 0.129941
Train Epoch: 14 [25600/60000 (43%)] Loss: 0.099867
Train Epoch: 14 [32000/60000 (53%)] Loss: 0.175463
Train Epoch: 14 [38400/60000 (64%)] Loss: 0.075817
Train Epoch: 14 [44800/60000 (75%)] Loss: 0.191533
Train Epoch: 14 [51200/60000 (85%)] Loss: 0.105866
Train Epoch: 14 [57600/60000 (96%)] Loss: 0.255987
Test set: Average loss: 0.0875, Accuracy: 9751/10000 (98%)
Train Epoch: 15 [0/60000 (0%)] Loss: 0.049678
Train Epoch: 15 [6400/60000 (11%)] Loss: 0.185887
Train Epoch: 15 [12800/60000 (21%)] Loss: 0.064999
Train Epoch: 15 [19200/60000 (32%)] Loss: 0.106103
Train Epoch: 15 [25600/60000 (43%)] Loss: 0.052213
Train Epoch: 15 [32000/60000 (53%)] Loss: 0.136051
Train Epoch: 15 [38400/60000 (64%)] Loss: 0.037222
Train Epoch: 15 [44800/60000 (75%)] Loss: 0.152106
Train Epoch: 15 [51200/60000 (85%)] Loss: 0.140182
Train Epoch: 15 [57600/60000 (96%)] Loss: 0.216424
Test set: Average loss: 0.0850, Accuracy: 9757/10000 (98%)
如何运行这段代码:
不要在Jupyter笔记上直接运行
请将左侧的 `experiments/mnist/train.py` 文件下载到本地
安装相关依赖包: pip install torch torchvision
运行:python3 train.py
在 HuggingFace 上找一个简单的数据集,自己实现一个训练过程
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