Multi lstm layers and multi lstm in pytorch

Question

I am using two ways to create a two-layer lstm as shown in the following two codes. Can anyone tell me why the outputs are not the same? and If you have the experience, can you tell me which one is better ? Thanks so much ! (Thanks for the suggestion of initializing them to have the same weights and bias. I add this suggestion in the original code. Despite the same initial parameters, their outputs are still not the same...)

The first way using num_layers:

import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim

torch.manual_seed(1)

lstm = nn.LSTM(3, 3,2)  # Input dim is 3, output dim is 3
inputs = [torch.randn(1, 3) for _ in range(5)]  # make a sequence of length 5

weight_ih_0=None
weight_hh_0=None
# bias_ih_0=None
# bias_hh_0=None

weight_ih_1=None
weight_hh_1=None
# bias_ih_1=None
# bias_hh_1=None

for name, param in lstm.named_parameters():
  if 'bias' in name:
     # print(f'bias {name} before init: {param}')
     nn.init.constant_(param, 0.0)
     # print(f'bias {name} after init: {param}')
  elif 'weight' in name:
     # print(f'weight {name} before init: {param}')
     nn.init.xavier_normal_(param)
     print(f'weight {name} after init: {param}')

for name, param in lstm.named_parameters():
    if 'weight_ih_l0' in name:
        weight_ih_0=param
    if 'weight_hh_l0' in name:
        weight_hh_0=param
    if 'weight_ih_l1' in name:
        weight_ih_1=param
    if 'weight_hh_l1' in name:
        weight_hh_1=param
    
print(f'inputs: {inputs}')

# initialize the hidden state.
hidden = (torch.zeros(2, 1, 3),
          torch.zeros(2, 1, 3))

idx=0
for i in inputs:
    print(f'idx: {idx}')
    
    # print(f'i: {i}')
    
    idx+=1
    
    # Step through the sequence one element at a time.
    # after each step, hidden contains the hidden
    out, hidden = lstm(i.view(1, 1, -1), hidden)

    print(out)
    
    print("==========")
    
    # print(hidden)

The outputs is:

weight weight_ih_l0 after init: Parameter containing:
tensor([[ 0.6025, -0.1577, -0.0990],
        [-0.5255,  0.4554,  0.4651],
        [ 0.1428,  0.1414, -0.0291],
        [ 0.1248,  0.3465, -0.5053],
        [ 0.6295, -0.8635, -0.3394],
        [ 0.1072,  0.0786,  0.3427],
        [ 0.5352, -0.2032,  0.8816],
        [ 0.3727, -0.1608, -0.6332],
        [-0.3745,  0.1903, -0.1654],
        [-0.0460, -0.2148,  0.7737],
        [-0.1980, -0.8980, -0.3470],
        [-0.1130,  0.6074,  0.1844]], requires_grad=True)
weight weight_hh_l0 after init: Parameter containing:
tensor([[-0.0719, -0.0122,  0.2626],
        [ 0.3887, -0.3044, -0.4356],
        [-0.8422,  0.2204,  0.1151],
        [ 0.4171,  0.1116, -0.2114],
        [ 0.2061, -0.3204, -0.0983],
        [ 0.4791, -0.5683, -0.3928],
        [-0.3196, -0.1726, -0.0732],
        [-0.3058, -0.5667, -0.0211],
        [-0.0832, -0.3168,  0.1241],
        [-0.4197,  0.0525,  0.0741],
        [ 0.3849,  0.0481, -0.3130],
        [ 0.5788,  0.6312, -0.3627]], requires_grad=True)
weight weight_ih_l1 after init: Parameter containing:
tensor([[ 3.6955e-02,  7.1276e-02, -4.3073e-01],
        [-5.2666e-01,  2.7323e-02,  1.2894e-01],
        [ 3.7136e-01,  3.3969e-01,  1.9601e-01],
        [ 3.5802e-01, -4.3600e-01, -1.7962e-01],
        [ 8.3209e-01,  1.7189e-01,  2.2195e-01],
        [-2.1302e-02, -1.6867e-01, -1.3460e-01],
        [ 1.3446e-01,  1.7708e-01, -5.6676e-01],
        [-2.3697e-01, -2.8254e-02, -2.2063e-01],
        [-2.0928e-01,  3.4973e-01,  3.5858e-04],
        [-5.0565e-01, -6.8619e-02,  3.7702e-01],
        [-9.0796e-02, -1.7238e-01,  4.7868e-01],
        [-1.1565e-01, -6.7956e-02, -2.1049e-01]], requires_grad=True)
weight weight_hh_l1 after init: Parameter containing:
tensor([[-0.3017, -0.0811, -0.6554],
        [ 0.2665, -0.2052, -0.0577],
        [ 0.5493, -0.5094,  0.2167],
        [ 0.1210, -0.3868, -0.2293],
        [-0.0991,  0.6744, -0.0114],
        [-0.0343, -0.6136,  0.4856],
        [ 0.0505,  0.3920, -0.1662],
        [ 0.1163, -0.1296,  0.2505],
        [-0.1373, -0.8803, -0.4666],
        [-0.0230, -0.0346, -0.8451],
        [ 0.2032,  0.1847, -0.0758],
        [ 0.2533,  0.1532,  0.8224]], requires_grad=True)
inputs: [tensor([[1.5381, 1.4673, 1.5951]]), tensor([[-1.5279,  1.0156, -0.2020]]), tensor([[-1.2865,  0.8231, -0.6101]]), tensor([[-1.2960, -0.9434,  0.6684]]), tensor([[ 1.1628, -0.3229,  1.8782]])]
idx: 0
tensor([[[ 0.0374, -0.0085, -0.0240]]], grad_fn=<StackBackward>)
==========
idx: 1
tensor([[[ 0.0073, -0.0110, -0.0296]]], grad_fn=<StackBackward>)
==========
idx: 2
tensor([[[-0.0314, -0.0147, -0.0136]]], grad_fn=<StackBackward>)
==========
idx: 3
tensor([[[-0.0458, -0.0118, -0.0254]]], grad_fn=<StackBackward>)
==========
idx: 4
tensor([[[-0.0096, -0.0281, -0.0440]]], grad_fn=<StackBackward>)
==========

The second way creating two individual lstm:

import copy

torch.manual_seed(1)

lstm = nn.LSTMCell(3, 3)  # Input dim is 3, output dim is 3
lstm2 = nn.LSTMCell(3, 3)  # Input dim is 3, output dim is 3
inputs = [torch.randn(1, 3) for _ in range(5)]  # make a sequence of length 5

for name, param in lstm.named_parameters():
  if 'bias' in name:
     # print(f'lstm bias {name} before init: {param}')
     nn.init.constant_(param, 0.0)
     # print(f'lstm bias {name} after init: {param}')
  elif 'weight' in name:
      
     # print(f'lstm weight {name} before init: {param}')
     if 'weight_ih' in name:
         param=copy.deepcopy(weight_ih_0)
         print(f'lstm {name} after init: {param}')
     if 'weight_hh' in name:
         param=copy.deepcopy(weight_hh_0)
         print(f'lstm {name} after init: {param}')
     
for name, param in lstm2.named_parameters():
  if 'bias' in name:
     # print(f'lstm2 bias {name} before init: {param}')
     nn.init.constant_(param, 0.0)
     # print(f'lstm2 bias {name} after init: {param}')
  elif 'weight' in name:
     # print(f'lstm2 weight {name} before init: {param}')
     if 'weight_ih' in name:
         param=copy.deepcopy(weight_ih_1)
         print(f'lstm2 {name} after init: {param}')
     if 'weight_hh' in name:
         param=copy.deepcopy(weight_hh_1)
         print(f'lstm2 {name} after init: {param}')

print(f'inputs: {inputs}')

# initialize the hidden state.
hidden = torch.zeros(1, 3)
cell= torch.zeros(1, 3)

idx=0
for i in inputs:
    print(f'idx: {idx}')
    
    idx+=1
    
    # Step through the sequence one element at a time.
    # after each step, hidden contains the hidden
    hidden, cell = lstm(i.view(1, -1), (hidden,cell))
    # print(hidden.shape)
    hidden, cell = lstm2(hidden, (hidden,cell))

    print(hidden)
    
    print("==========")

And the output is:

lstm weight_ih after init: Parameter containing:
tensor([[ 0.6025, -0.1577, -0.0990],
        [-0.5255,  0.4554,  0.4651],
        [ 0.1428,  0.1414, -0.0291],
        [ 0.1248,  0.3465, -0.5053],
        [ 0.6295, -0.8635, -0.3394],
        [ 0.1072,  0.0786,  0.3427],
        [ 0.5352, -0.2032,  0.8816],
        [ 0.3727, -0.1608, -0.6332],
        [-0.3745,  0.1903, -0.1654],
        [-0.0460, -0.2148,  0.7737],
        [-0.1980, -0.8980, -0.3470],
        [-0.1130,  0.6074,  0.1844]], requires_grad=True)
lstm weight_hh after init: Parameter containing:
tensor([[-0.0719, -0.0122,  0.2626],
        [ 0.3887, -0.3044, -0.4356],
        [-0.8422,  0.2204,  0.1151],
        [ 0.4171,  0.1116, -0.2114],
        [ 0.2061, -0.3204, -0.0983],
        [ 0.4791, -0.5683, -0.3928],
        [-0.3196, -0.1726, -0.0732],
        [-0.3058, -0.5667, -0.0211],
        [-0.0832, -0.3168,  0.1241],
        [-0.4197,  0.0525,  0.0741],
        [ 0.3849,  0.0481, -0.3130],
        [ 0.5788,  0.6312, -0.3627]], requires_grad=True)
lstm2 weight_ih after init: Parameter containing:
tensor([[ 3.6955e-02,  7.1276e-02, -4.3073e-01],
        [-5.2666e-01,  2.7323e-02,  1.2894e-01],
        [ 3.7136e-01,  3.3969e-01,  1.9601e-01],
        [ 3.5802e-01, -4.3600e-01, -1.7962e-01],
        [ 8.3209e-01,  1.7189e-01,  2.2195e-01],
        [-2.1302e-02, -1.6867e-01, -1.3460e-01],
        [ 1.3446e-01,  1.7708e-01, -5.6676e-01],
        [-2.3697e-01, -2.8254e-02, -2.2063e-01],
        [-2.0928e-01,  3.4973e-01,  3.5858e-04],
        [-5.0565e-01, -6.8619e-02,  3.7702e-01],
        [-9.0796e-02, -1.7238e-01,  4.7868e-01],
        [-1.1565e-01, -6.7956e-02, -2.1049e-01]], requires_grad=True)
lstm2 weight_hh after init: Parameter containing:
tensor([[-0.3017, -0.0811, -0.6554],
        [ 0.2665, -0.2052, -0.0577],
        [ 0.5493, -0.5094,  0.2167],
        [ 0.1210, -0.3868, -0.2293],
        [-0.0991,  0.6744, -0.0114],
        [-0.0343, -0.6136,  0.4856],
        [ 0.0505,  0.3920, -0.1662],
        [ 0.1163, -0.1296,  0.2505],
        [-0.1373, -0.8803, -0.4666],
        [-0.0230, -0.0346, -0.8451],
        [ 0.2032,  0.1847, -0.0758],
        [ 0.2533,  0.1532,  0.8224]], requires_grad=True)
inputs: [tensor([[1.5381, 1.4673, 1.5951]]), tensor([[-1.5279,  1.0156, -0.2020]]), tensor([[-1.2865,  0.8231, -0.6101]]), tensor([[-1.2960, -0.9434,  0.6684]]), tensor([[ 1.1628, -0.3229,  1.8782]])]
idx: 0
tensor([[-0.0152, -0.0344,  0.0368]], grad_fn=<MulBackward0>)
==========
idx: 1
tensor([[-0.0265, -0.0143,  0.0730]], grad_fn=<MulBackward0>)
==========
idx: 2
tensor([[-0.0210, -0.0033,  0.0529]], grad_fn=<MulBackward0>)
==========
idx: 3
tensor([[-0.0580, -0.0201,  0.1194]], grad_fn=<MulBackward0>)
==========
idx: 4
tensor([[-0.0672, -0.0801,  0.1165]], grad_fn=<MulBackward0>)
==========

I know you tried seeding, but have you checked whether the two networks have identical weights? — Jake Tae, Mar 26, 2022 at 23:28
Thanks for the answer. You're right, the initial weights and bias are not the same. However, even though I initialize them to have the same values, the outputs are still different. So, I have the doubt that "num_layers" is in fact not the same thing as explained in discuss.pytorch.org/t/what-is-num-layers-in-rnn-module/9843. I add the outputs after having initialized them to have the same values as follows. — Mingming Qiu, Mar 27, 2022 at 13:50
The code having the same initial parameters and the corresponding outputs of the model are in the above-modified code. — Mingming Qiu, Mar 27, 2022 at 14:01

ki-ljl · Accepted Answer · 2022-03-27 03:29:41Z

0

Although you initialized two LSTMs, obviously the initial weights of the two are different. You can verify this with the following code:

for p in lstm.parameters():
    print(p)

I may prefer the first method, because this method does not require us to manually link between multiple layers.

answered Mar 27, 2022 at 3:29

ki-ljl

5092 silver badges9 bronze badges

Thanks for the answer. You're right, the initial weights and bias are not the same. However, even though I initialize them to have the same values, the outputs are still different. So, I have the doubt that "num_layers" is in fact not the same thing as explained in discuss.pytorch.org/t/what-is-num-layers-in-rnn-module/9843. I add the outputs after having initialized them to have the same values as follows.
– Mingming Qiu
Mar 27, 2022 at 13:51
The code having the same initial parameters and the corresponding outputs of the model are in the above-modified code.
– Mingming Qiu
Mar 27, 2022 at 14:02

Add a comment |

Mingming Qiu · Accepted Answer · 2022-03-28 19:47:23Z

I have the answer now. At the very beginning, I was confused with the hidden state and input state of the second lstm layer.

Thus, for stacked lstm with num_layers=2, we initialize the hidden states with the number of 2, since each lstm layer needs the initial hidden state, while the second lstm layer takes the output hidden state of the first lstm layer as its input.

And for the model containing individual lstm, since, for the above-stacked lstm model, each lstm layer has the initial hidden states being 0, thus, we should initialize the two individual lstms to both have zero hidden states.

In addition, I made a mistake to initialize the weight and bias values.

As a result, to make the above two methods have the same outputs, I use the following codes:

the first method:

import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim

torch.manual_seed(1)

lstm = nn.LSTM(3, 3,2)  # Input dim is 3, output dim is 3
inputs = [torch.randn(1, 3) for _ in range(5)]  # make a sequence of length 5

weight_ih_0=None
weight_hh_0=None
# bias_ih_0=None
# bias_hh_0=None

weight_ih_1=None
weight_hh_1=None
# bias_ih_1=None
# bias_hh_1=None

for name, param in lstm.named_parameters():
  if 'bias' in name:
     # print(f'bias {name} before init: {param}')
     nn.init.constant_(param, 0.0)
     # print(f'bias {name} after init: {param}')
  elif 'weight' in name:
     # print(f'weight {name} before init: {param}')
     nn.init.xavier_normal_(param)
     print(f'weight {name} after init: {param}')

for name, param in lstm.named_parameters():
    if 'weight_ih_l0' in name:
        weight_ih_0=param
    if 'weight_hh_l0' in name:
        weight_hh_0=param
    if 'weight_ih_l1' in name:
        weight_ih_1=param
    if 'weight_hh_l1' in name:
        weight_hh_1=param
    
print(f'inputs: {inputs}')

# initialize the hidden state.
hidden = (torch.zeros(2, 1, 3),
          torch.zeros(2, 1, 3))

idx=0
for i in inputs:
    print(f'idx: {idx}')
    
    # print(f'i: {i}')
    
    idx+=1
    
    # Step through the sequence one element at a time.
    # after each step, hidden contains the hidden
    out, hidden = lstm(i.view(1, 1, -1), hidden)

    print(out)
    
    
    
    # print(hidden)
    
    print("==========")

And the output is:

weight weight_ih_l0 after init: Parameter containing:
tensor([[ 0.6025, -0.1577, -0.0990],
        [-0.5255,  0.4554,  0.4651],
        [ 0.1428,  0.1414, -0.0291],
        [ 0.1248,  0.3465, -0.5053],
        [ 0.6295, -0.8635, -0.3394],
        [ 0.1072,  0.0786,  0.3427],
        [ 0.5352, -0.2032,  0.8816],
        [ 0.3727, -0.1608, -0.6332],
        [-0.3745,  0.1903, -0.1654],
        [-0.0460, -0.2148,  0.7737],
        [-0.1980, -0.8980, -0.3470],
        [-0.1130,  0.6074,  0.1844]], requires_grad=True)
weight weight_hh_l0 after init: Parameter containing:
tensor([[-0.0719, -0.0122,  0.2626],
        [ 0.3887, -0.3044, -0.4356],
        [-0.8422,  0.2204,  0.1151],
        [ 0.4171,  0.1116, -0.2114],
        [ 0.2061, -0.3204, -0.0983],
        [ 0.4791, -0.5683, -0.3928],
        [-0.3196, -0.1726, -0.0732],
        [-0.3058, -0.5667, -0.0211],
        [-0.0832, -0.3168,  0.1241],
        [-0.4197,  0.0525,  0.0741],
        [ 0.3849,  0.0481, -0.3130],
        [ 0.5788,  0.6312, -0.3627]], requires_grad=True)
weight weight_ih_l1 after init: Parameter containing:
tensor([[ 3.6955e-02,  7.1276e-02, -4.3073e-01],
        [-5.2666e-01,  2.7323e-02,  1.2894e-01],
        [ 3.7136e-01,  3.3969e-01,  1.9601e-01],
        [ 3.5802e-01, -4.3600e-01, -1.7962e-01],
        [ 8.3209e-01,  1.7189e-01,  2.2195e-01],
        [-2.1302e-02, -1.6867e-01, -1.3460e-01],
        [ 1.3446e-01,  1.7708e-01, -5.6676e-01],
        [-2.3697e-01, -2.8254e-02, -2.2063e-01],
        [-2.0928e-01,  3.4973e-01,  3.5858e-04],
        [-5.0565e-01, -6.8619e-02,  3.7702e-01],
        [-9.0796e-02, -1.7238e-01,  4.7868e-01],
        [-1.1565e-01, -6.7956e-02, -2.1049e-01]], requires_grad=True)
weight weight_hh_l1 after init: Parameter containing:
tensor([[-0.3017, -0.0811, -0.6554],
        [ 0.2665, -0.2052, -0.0577],
        [ 0.5493, -0.5094,  0.2167],
        [ 0.1210, -0.3868, -0.2293],
        [-0.0991,  0.6744, -0.0114],
        [-0.0343, -0.6136,  0.4856],
        [ 0.0505,  0.3920, -0.1662],
        [ 0.1163, -0.1296,  0.2505],
        [-0.1373, -0.8803, -0.4666],
        [-0.0230, -0.0346, -0.8451],
        [ 0.2032,  0.1847, -0.0758],
        [ 0.2533,  0.1532,  0.8224]], requires_grad=True)
inputs: [tensor([[1.5381, 1.4673, 1.5951]]), tensor([[-1.5279,  1.0156, -0.2020]]), tensor([[-1.2865,  0.8231, -0.6101]]), tensor([[-1.2960, -0.9434,  0.6684]]), tensor([[ 1.1628, -0.3229,  1.8782]])]
idx: 0
tensor([[[ 0.0374, -0.0085, -0.0240]]], grad_fn=<StackBackward>)
==========
idx: 1
tensor([[[ 0.0073, -0.0110, -0.0296]]], grad_fn=<StackBackward>)
==========
idx: 2
tensor([[[-0.0314, -0.0147, -0.0136]]], grad_fn=<StackBackward>)
==========
idx: 3
tensor([[[-0.0458, -0.0118, -0.0254]]], grad_fn=<StackBackward>)
==========
idx: 4
tensor([[[-0.0096, -0.0281, -0.0440]]], grad_fn=<StackBackward>)
==========

The second method:

torch.manual_seed(1)

lstm = nn.LSTM(3, 3,1)  # Input dim is 3, output dim is 3
lstm2 = nn.LSTM(3, 3,1)  # Input dim is 3, output dim is 3
inputs = [torch.randn(1, 3) for _ in range(5)]  # make a sequence of length 5

print(f'inputs: {inputs}')

# initialize the hidden state.
hidden1 = (torch.zeros(1, 1, 3),
          torch.zeros(1, 1, 3))

hidden2 = (torch.zeros(1, 1, 3),
          torch.zeros(1, 1, 3))


for name, param in lstm.named_parameters():
  if 'bias' in name:
      # print(f'lstm bias {name} before init: {param}')
      nn.init.constant_(param, 0.0)
      # print(f'lstm bias {name} after init: {param}')
  elif 'weight' in name:
      
      # print(f'lstm weight {name} before init: {param}')
      if 'weight_ih' in name:
          lstm.weight_ih_l0.data=weight_ih_0
          print(f'lstm {name} after init: {param}')
      if 'weight_hh' in name:
          lstm.weight_hh_l0.data=weight_hh_0
          print(f'lstm {name} after init: {param}')
     
for name, param in lstm2.named_parameters():
  if 'bias' in name:
      # print(f'lstm2 bias {name} before init: {param}')
      nn.init.constant_(param, 0.0)
      # print(f'lstm2 bias {name} after init: {param}')
  elif 'weight' in name:
      # print(f'lstm2 weight {name} before init: {param}')
      if 'weight_ih' in name:
          lstm2.weight_ih_l0.data=weight_ih_1
          print(f'lstm2 {name} after init: {param}')
      if 'weight_hh' in name:
          lstm2.weight_hh_l0.data=weight_hh_1
          print(f'lstm2 {name} after init: {param}')
          
for name, param in lstm2.named_parameters():
  if 'weight' in name:
      # print(f'lstm2 weight {name} before init: {param}')
     
      print(f'lstm2 {name} after init: {param}')
     
idx=0

for i in inputs:
    print(f'idx: {idx}')
    
    idx+=1
    
    # Step through the sequence one element at a time.
    # after each step, hidden contains the hidden
    out, hidden1 = lstm(i.view(1, 1, -1), hidden1)
    out, hidden2 = lstm2(out.view(1, 1, -1), hidden2)

    print(out)
    
    print("==========")

And the output is:

inputs: [tensor([[1.5381, 1.4673, 1.5951]]), tensor([[-1.5279,  1.0156, -0.2020]]), tensor([[-1.2865,  0.8231, -0.6101]]), tensor([[-1.2960, -0.9434,  0.6684]]), tensor([[ 1.1628, -0.3229,  1.8782]])]
lstm weight_ih_l0 after init: Parameter containing:
tensor([[ 0.6025, -0.1577, -0.0990],
        [-0.5255,  0.4554,  0.4651],
        [ 0.1428,  0.1414, -0.0291],
        [ 0.1248,  0.3465, -0.5053],
        [ 0.6295, -0.8635, -0.3394],
        [ 0.1072,  0.0786,  0.3427],
        [ 0.5352, -0.2032,  0.8816],
        [ 0.3727, -0.1608, -0.6332],
        [-0.3745,  0.1903, -0.1654],
        [-0.0460, -0.2148,  0.7737],
        [-0.1980, -0.8980, -0.3470],
        [-0.1130,  0.6074,  0.1844]], requires_grad=True)
lstm weight_hh_l0 after init: Parameter containing:
tensor([[-0.0719, -0.0122,  0.2626],
        [ 0.3887, -0.3044, -0.4356],
        [-0.8422,  0.2204,  0.1151],
        [ 0.4171,  0.1116, -0.2114],
        [ 0.2061, -0.3204, -0.0983],
        [ 0.4791, -0.5683, -0.3928],
        [-0.3196, -0.1726, -0.0732],
        [-0.3058, -0.5667, -0.0211],
        [-0.0832, -0.3168,  0.1241],
        [-0.4197,  0.0525,  0.0741],
        [ 0.3849,  0.0481, -0.3130],
        [ 0.5788,  0.6312, -0.3627]], requires_grad=True)
lstm2 weight_ih_l0 after init: Parameter containing:
tensor([[ 3.6955e-02,  7.1276e-02, -4.3073e-01],
        [-5.2666e-01,  2.7323e-02,  1.2894e-01],
        [ 3.7136e-01,  3.3969e-01,  1.9601e-01],
        [ 3.5802e-01, -4.3600e-01, -1.7962e-01],
        [ 8.3209e-01,  1.7189e-01,  2.2195e-01],
        [-2.1302e-02, -1.6867e-01, -1.3460e-01],
        [ 1.3446e-01,  1.7708e-01, -5.6676e-01],
        [-2.3697e-01, -2.8254e-02, -2.2063e-01],
        [-2.0928e-01,  3.4973e-01,  3.5858e-04],
        [-5.0565e-01, -6.8619e-02,  3.7702e-01],
        [-9.0796e-02, -1.7238e-01,  4.7868e-01],
        [-1.1565e-01, -6.7956e-02, -2.1049e-01]], requires_grad=True)
lstm2 weight_hh_l0 after init: Parameter containing:
tensor([[-0.3017, -0.0811, -0.6554],
        [ 0.2665, -0.2052, -0.0577],
        [ 0.5493, -0.5094,  0.2167],
        [ 0.1210, -0.3868, -0.2293],
        [-0.0991,  0.6744, -0.0114],
        [-0.0343, -0.6136,  0.4856],
        [ 0.0505,  0.3920, -0.1662],
        [ 0.1163, -0.1296,  0.2505],
        [-0.1373, -0.8803, -0.4666],
        [-0.0230, -0.0346, -0.8451],
        [ 0.2032,  0.1847, -0.0758],
        [ 0.2533,  0.1532,  0.8224]], requires_grad=True)
lstm2 weight_ih_l0 after init: Parameter containing:
tensor([[ 3.6955e-02,  7.1276e-02, -4.3073e-01],
        [-5.2666e-01,  2.7323e-02,  1.2894e-01],
        [ 3.7136e-01,  3.3969e-01,  1.9601e-01],
        [ 3.5802e-01, -4.3600e-01, -1.7962e-01],
        [ 8.3209e-01,  1.7189e-01,  2.2195e-01],
        [-2.1302e-02, -1.6867e-01, -1.3460e-01],
        [ 1.3446e-01,  1.7708e-01, -5.6676e-01],
        [-2.3697e-01, -2.8254e-02, -2.2063e-01],
        [-2.0928e-01,  3.4973e-01,  3.5858e-04],
        [-5.0565e-01, -6.8619e-02,  3.7702e-01],
        [-9.0796e-02, -1.7238e-01,  4.7868e-01],
        [-1.1565e-01, -6.7956e-02, -2.1049e-01]], requires_grad=True)
lstm2 weight_hh_l0 after init: Parameter containing:
tensor([[-0.3017, -0.0811, -0.6554],
        [ 0.2665, -0.2052, -0.0577],
        [ 0.5493, -0.5094,  0.2167],
        [ 0.1210, -0.3868, -0.2293],
        [-0.0991,  0.6744, -0.0114],
        [-0.0343, -0.6136,  0.4856],
        [ 0.0505,  0.3920, -0.1662],
        [ 0.1163, -0.1296,  0.2505],
        [-0.1373, -0.8803, -0.4666],
        [-0.0230, -0.0346, -0.8451],
        [ 0.2032,  0.1847, -0.0758],
        [ 0.2533,  0.1532,  0.8224]], requires_grad=True)
idx: 0
tensor([[[ 0.0374, -0.0085, -0.0240]]], grad_fn=<StackBackward>)
==========
idx: 1
tensor([[[ 0.0073, -0.0110, -0.0296]]], grad_fn=<StackBackward>)
==========
idx: 2
tensor([[[-0.0314, -0.0147, -0.0136]]], grad_fn=<StackBackward>)
==========
idx: 3
tensor([[[-0.0458, -0.0118, -0.0254]]], grad_fn=<StackBackward>)
==========
idx: 4
tensor([[[-0.0096, -0.0281, -0.0440]]], grad_fn=<StackBackward>)
==========

Collectives™ on Stack Overflow

Multi lstm layers and multi lstm in pytorch

2 Answers 2

Your Answer

Not the answer you're looking for? Browse other questions tagged
python
pytorch
lstm
or ask your own question.

Hot Network Questions

Collectives™ on Stack Overflow

2 Answers 2

Your Answer

Sign up or log in

Post as a guest

Not the answer you're looking for? Browse other questions tagged pythonpytorchlstm or ask your own question.

Related

Not the answer you're looking for? Browse other questions tagged
python
pytorch
lstm
or ask your own question.