I was going through this example of a LSTM language model on github (link). What it does in general is pretty clear to me. But I'm still struggling to understand what calling contiguous() does, which occurs several times in the code.

For example in line 74/75 of the code input and target sequences of the LSTM are created. Data (stored in ids) is 2-dimensional where first dimension is the batch size.

for i in range(0, ids.size(1) - seq_length, seq_length):
    # Get batch inputs and targets
    inputs = Variable(ids[:, i:i+seq_length])
    targets = Variable(ids[:, (i+1):(i+1)+seq_length].contiguous())

So as a simple example, when using batch size 1 and seq_length 10 inputs and targets looks like this:

inputs Variable containing:
0     1     2     3     4     5     6     7     8     9
[torch.LongTensor of size 1x10]

targets Variable containing:
1     2     3     4     5     6     7     8     9    10
[torch.LongTensor of size 1x10]

So in general my question is, what does contiguous() and why do I need it?

Further I don't understand why the method is called for the target sequence and but not the input sequence as both variables are comprised of the same data.

How could targets be uncontiguous and inputs still be contiguous?

EDIT: I tried to leave out calling contiguous(), but this leads to an error message when computing the loss.

RuntimeError: invalid argument 1: input is not contiguous at .../src/torch/lib/TH/generic/THTensor.c:231

So obviously calling contiguous() in this example is necessary.

(For keeping this readable I avoided posting the full code here, it can be found by using the GitHub link above.)

Thanks in advance!


There are few operations on Tensor in PyTorch that do not really change the content of the tensor, but only how to convert indices in to tensor to byte location. These operations include:

narrow(), view(), expand() and transpose()

For example: when you call transpose(), PyTorch doesn't generate new tensor with new layout, it just modifies meta information in Tensor object so offset and stride are for new shape. The transposed tensor and original tensor are indeed sharing the memory!

x = torch.randn(3,2)
y = torch.transpose(x, 0, 1)
x[0, 0] = 42
# prints 42

This is where the concept of contiguous comes in. Above x is contiguous but y is not because its memory layout is different than a tensor of same shape made from scratch. Note that the word "contiguous" is bit misleading because its not that the content of tensor is spread out around disconnected blocks of memory. Here bytes are still allocated in one block of memory but the order of the elements is different!

When you call contiguous(), it actually makes a copy of tensor so the order of elements would be same as if tensor of same shape created from scratch.

Normally you don't need to worry about this. If PyTorch expects contiguous tensor but if its not then you will get RuntimeError: input is not contiguous and then you just add a call to contiguous().

| improve this answer | |
  • I just came across this again. Your explanation is very good! I just wonder: If the blocks in memory are not widely spread, what is the problem with a memory layout that is "different than a tensor of same shape made from scratch"? Why is being contiguous only requirement for some operations? – MBT Nov 13 '18 at 17:35
  • 4
    I can't definitively answer this but my guess is that some of the PyTorch code uses high performance vectorized implementation of the operations implemented in C++ and this code cannot use arbitrary offset/strides specified in Tensor's meta information. This is just a guess though. – Shital Shah Nov 16 '18 at 11:15
  • 1
    Why couldn't the callee simply call contiguous() by itself? – information_interchange Feb 23 '19 at 21:25
  • quite possibly, because you don't want it in a contiguous way, and it is always nice to have control over what you do. – shivam13juna Jun 17 '19 at 12:58
  • 2
    Another popular tensor operation is permute, which also may return non-"contiguous" tensor. – Oleg Nov 18 '19 at 7:18

From the [pytorch documentation][1]:

contiguous() → Tensor

Returns a contiguous tensor containing the same data as self 

tensor. If self tensor is contiguous, this function returns the self tensor.

Where contiguous here means not only contiguous in memory, but also in the same order in memory as the indices order: for example doing a transposition doesn't change the data in memory, it simply changes the map from indices to memory pointers, if you then apply contiguous() it will change the data in memory so that the map from indices to memory location is the canonical one. [1]: http://pytorch.org/docs/master/tensors.html

| improve this answer | |
  • 1
    Thank you for your answer! Can you tell me why/when I need the data to be contiguous? Is it just performance, or some other reason? Does PyTorch require contiguous data for some operations? Why does targets need to be contiguous and inputs not? – MBT Feb 22 '18 at 9:10
  • It is just for performance. I don't know why the codes does it for targets but not for inputs. – patapouf_ai Feb 22 '18 at 12:42
  • 2
    So apparently pytorch requires the targets in the loss to be continguous in memory, but the inputs of neuralnet don't need to satisfy this requirement. – patapouf_ai Feb 23 '18 at 8:16
  • 2
    Great thank you! I think this makes sense to me, I've noticed that contiguous() is also applied to the output data (which was of course formerly the input) in the forward function, so both outputs and targets are contiguous when computing the loss. Thanks a lot! – MBT Feb 23 '18 at 10:09
  • 1
    @patapouf_ai No. Your explanation of it is incorrect. As pointed out in the correct answer, it is not about contiguous blocks of memory at all. – Akaisteph7 Jul 1 at 20:55

tensor.contiguous() will create a copy of the tensor, and the element in the copy will be stored in the memory in a contiguous way. The contiguous() function is usually required when we first transpose() a tensor and then reshape (view) it. First, let's create a contiguous tensor:

aaa = torch.Tensor( [[1,2,3],[4,5,6]] )

The stride() return (3,1) means that: when moving along the first dimension by each step (row by row), we need to move 3 steps in the memory. When moving along the second dimension (column by column), we need to move 1 step in the memory. This indicates that the elements in the tensor are stored contiguously.

Now we try apply come functions to the tensor:

bbb = aaa.transpose(0,1)

ccc = aaa.narrow(1,1,2)   ## equivalent to matrix slicing aaa[:,1:3]

ddd = aaa.repeat(2,1 )   # The first dimension repeat once, the second dimension repeat twice

## expand is different from repeat  if a tensor has a shape [d1,d2,1], it can only be expanded using "expand(d1,d2,d3)", which
## means the singleton dimension is repeated d3 times
eee = aaa.unsqueeze(2).expand(2,3,3)

fff = aaa.unsqueeze(2).repeat(1,1,8).view(2,-1,2)

#(1, 3)
#(3, 1)
#(3, 1)
#(3, 1, 0)
#(24, 2, 1)

Ok, we can find that transpose(), narrow() and tensor slicing, and expand() will make the generated tensor not contiguous. Interestingly, repeat() and view() does not make it discontiguous. So now the question is: what happens if I use a discontiguous tensor?

The answer is it the view() function cannot be applied to a discontiguous tensor. This is probably because view() requires that the tensor to be contiguously stored so that it can do fast reshape in memory. e.g:


we will get the error:

RuntimeError                              Traceback (most recent call last)
<ipython-input-63-eec5319b0ac5> in <module>()
----> 1 bbb.view(-1,3)

RuntimeError: invalid argument 2: view size is not compatible with input tensor's size and stride (at least one dimension spans across two contiguous subspaces). Call .contiguous() before .view(). at /pytorch/aten/src/TH/generic/THTensor.cpp:203

To solve this, simply add contiguous() to a discontiguous tensor, to create contiguous copy and then apply view()

#tensor([[1., 4., 2.],
        [5., 3., 6.]])
| improve this answer | |

As in the previous answer contigous() allocates contigous memory chunks, it'll be helpful when we're passing tensor to c or c++ backend code where tensors are passed as pointers

| improve this answer | |

From what I understand this a more summarized answer:

Contiguous is the term used to indicate that the memory layout of a tensor does not align with its advertised meta-data or shape information.

In my opinion the word contiguous is a confusing/misleading term since in normal contexts it means when memory is not spread around in disconnected blocks (i.e. its "contiguous/connected/continuous").

Some operations might need this contiguous property for some reason (most likely efficiency in gpu etc).

Note that .view is another operation that might cause this issue. Look at the following code I fixed by simply calling contiguous (instead of the typical transpose issue causing it here is an example that is cause when an RNN is not happy with its input):

        # normal lstm([loss, grad_prep, train_err]) = lstm(xn)
        n_learner_params = xn_lstm.size(1)
        (lstmh, lstmc) = hs[0] # previous hx from first (standard) lstm i.e. lstm_hx = (lstmh, lstmc) = hs[0]
        if lstmh.size(1) != xn_lstm.size(1): # only true when prev lstm_hx is equal to decoder/controllers hx
            # make sure that h, c from decoder/controller has the right size to go into the meta-optimizer
            expand_size = torch.Size([1,n_learner_params,self.lstm.hidden_size])
            lstmh, lstmc = lstmh.squeeze(0).expand(expand_size).contiguous(), lstmc.squeeze(0).expand(expand_size).contiguous()
        lstm_out, (lstmh, lstmc) = self.lstm(input=xn_lstm, hx=(lstmh, lstmc))

Error I used to get:

RuntimeError: rnn: hx is not contiguous


| improve this answer | |

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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