这是我定义的模型,它是一个简单的LSTM,有两个完全连接的层。
import copy
import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim
class mylstm(nn.Module):
def __init__(self,input_dim, output_dim, hidden_dim,linear_dim):
super(mylstm, self).__init__()
self.hidden_dim=hidden_dim
self.lstm=nn.LSTMCell(input_dim,self.hidden_dim)
self.linear1=nn.Linear(hidden_dim,linear_dim)
self.linear2=nn.Linear(linear_dim,output_dim)
def forward(self, input):
out,_=self.lstm(input)
out=nn.Dropout(p=0.3)(out)
out=self.linear1(out)
out=nn.Dropout(p=0.3)(out)
out=self.linear2(out)
return out
x_train和x_val是形状为(4478,30)的浮动数据帧,而y_train和y_val是形状为(4478,10)的浮动df。 x_train.head()
Out[271]:
0 1 2 3 ... 26 27 28 29
0 1.6110 1.6100 1.6293 1.6370 ... 1.6870 1.6925 1.6950 1.6905
1 1.6100 1.6293 1.6370 1.6530 ... 1.6925 1.6950 1.6905 1.6960
2 1.6293 1.6370 1.6530 1.6537 ... 1.6950 1.6905 1.6960 1.6930
3 1.6370 1.6530 1.6537 1.6620 ... 1.6905 1.6960 1.6930 1.6955
4 1.6530 1.6537 1.6620 1.6568 ... 1.6960 1.6930 1.6955 1.7040
[5 rows x 30 columns]
x_train.shape
Out[272]: (4478, 30)
定义变量,做一次bp,可以得到有效损失为1.4941。
model=mylstm(30,10,200,100).double()
from torch import optim
optimizer=optim.RMSprop(model.parameters(), lr=0.001, alpha=0.9)
criterion=nn.L1Loss()
input_=torch.autograd.Variable(torch.from_numpy(np.array(x_train)))
target=torch.autograd.Variable(torch.from_numpy(np.array(y_train)))
input2_=torch.autograd.Variable(torch.from_numpy(np.array(x_val)))
target2=torch.autograd.Variable(torch.from_numpy(np.array(y_val)))
optimizer.zero_grad()
output=model(input_)
loss=criterion(output,target)
loss.backward()
optimizer.step()
moniter=criterion(model(input2_),target2)
moniter
Out[274]: tensor(1.4941, dtype=torch.float64, grad_fn=<L1LossBackward>)
但是我再次调用了forward函数,由于辍学的随机性,我得到了一个不同的数字。
moniter=criterion(model(input2_),target2)
moniter
Out[275]: tensor(1.4943, dtype=torch.float64, grad_fn=<L1LossBackward>)
我该怎么做才能消除预测短语中的所有辍学现象?
我试过了:
moniter=criterion(model.eval()(input2_),target2)
moniter
Out[282]: tensor(1.4942, dtype=torch.float64, grad_fn=<L1LossBackward>)
moniter=criterion(model.eval()(input2_),target2)
moniter
Out[283]: tensor(1.4945, dtype=torch.float64, grad_fn=<L1LossBackward>)
并传递一个附加参数p来控制退出:
import copy
import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim
class mylstm(nn.Module):
def __init__(self,input_dim, output_dim, hidden_dim,linear_dim,p):
super(mylstm, self).__init__()
self.hidden_dim=hidden_dim
self.lstm=nn.LSTMCell(input_dim,self.hidden_dim)
self.linear1=nn.Linear(hidden_dim,linear_dim)
self.linear2=nn.Linear(linear_dim,output_dim)
def forward(self, input,p):
out,_=self.lstm(input)
out=nn.Dropout(p=p)(out)
out=self.linear1(out)
out=nn.Dropout(p=p)(out)
out=self.linear2(out)
return out
model=mylstm(30,10,200,100,0.3).double()
output=model(input_)
loss=criterion(output,target)
loss.backward()
optimizer.step()
moniter=criterion(model(input2_,0),target2)
Traceback (most recent call last):
File "<ipython-input-286-e49b6fac918b>", line 1, in <module>
output=model(input_)
File "D:\Users\shan xu\Anaconda3\lib\site-packages\torch\nn\modules\module.py", line 489, in __call__
result = self.forward(*input, **kwargs)
TypeError: forward() missing 1 required positional argument: 'p'
但他们都没起作用。
最佳答案
您必须在nn.Dropout中定义__init__层并将其分配给模型,以便响应调用eval()。
所以像这样改变你的模式应该对你有用:
class mylstm(nn.Module):
def __init__(self,input_dim, output_dim, hidden_dim,linear_dim,p):
super(mylstm, self).__init__()
self.hidden_dim=hidden_dim
self.lstm=nn.LSTMCell(input_dim,self.hidden_dim)
self.linear1=nn.Linear(hidden_dim,linear_dim)
self.linear2=nn.Linear(linear_dim,output_dim)
# define dropout layer in __init__
self.drop_layer = nn.Dropout(p=p)
def forward(self, input):
out,_= self.lstm(input)
# apply model dropout, responsive to eval()
out= self.drop_layer(out)
out= self.linear1(out)
# apply model dropout, responsive to eval()
out= self.drop_layer(out)
out= self.linear2(out)
return out
如果您像这样更改它,那么一旦您调用
eval(),这个辍学将处于非活动状态。注意:如果您想在之后继续培训,您需要在您的模型上调用
train()以退出评估模式。您还可以在此处找到一个小的辍学工作示例,其中
eval()用于评估模式:nn.Dropout vs. F.dropout pyTorch