The Tensor class is probably the most important class in Torch. Almost every package depends on this class. It is the class for handling numeric data. As with pretty much anything in Torch7, tensors are serializable.
Multi-dimensional matrix
A Tensor is a potentially multi-dimensional matrix. The number of dimensions is unlimited that can be created using LongStorage with more dimensions.
Example:
--- creation of a 4D-tensor 4x5x6x2 z = torch.Tensor(4,5,6,2) --- for more dimensions, (here a 6D tensor) one can do: s = torch.LongStorage(6) s[1] = 4; s[2] = 5; s[3] = 6; s[4] = 2; s[5] = 7; s[6] = 3; x = torch.Tensor(s)
The number of dimensions of a Tensor can be queried by nDimension() or dim(). Size of the i-th dimension is returned by size(i). A LongStorage containing all the dimensions can be returned by size().
> print(x:nDimension()) 6 > print(x:size()) 4 5 6 2 7 3 [torch.LongStorage of size 6]
Internal data representation
The actual data of a Tensor is contained into a Storage. It can be accessed using storage(). While the memory of a Tensor has to be contained in this unique Storage, it might not be contiguous: the first position used in the Storage is given by storageOffset() (starting at 1). And the jump needed to go from one element to another element in the i-th dimension is given by stride(i). In other words, given a 3D tensor
x = torch.Tensor(7,7,7)
accessing the element (3,4,5) can be done by
= x[3][4][5]
or equivalently (but slowly!)
= x:storage()[x:storageOffset() +(3-1)*x:stride(1)+(4-1)*x:stride(2)+(5-1)*x:stride(3)]
One could say that a Tensor is a particular way of viewing a Storage: a Storage only represents a chunk of memory, while the Tensor interprets this chunk of memory as having dimensions:
> x = torch.Tensor(4,5) > s = x:storage() > for i=1,s:size() do -- fill up the Storage >> s[i] = i >> end > print(x) -- s is interpreted by x as a 2D matrix 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 [torch.DoubleTensor of dimension 4x5]
Note also that in Torch7 elements in the same row [elements along the last dimension] are contiguous in memory for a matrix [tensor]:
> x = torch.Tensor(4,5) > i = 0 > > x:apply(function() >> i = i + 1 >> return i >> end) > > print(x) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 [torch.DoubleTensor of dimension 4x5] > return x:stride() 5 1 -- element in the last dimension are contiguous! [torch.LongStorage of size 2]
This is exactly like in C (and not Fortran).
Tensors of different types
Actually, several types of Tensor exists:
ByteTensor -- contains unsigned chars CharTensor -- contains signed chars ShortTensor -- contains shorts IntTensor -- contains ints FloatTensor -- contains floats DoubleTensor -- contains doubles
Most numeric operations are implemented only for FloatTensor and DoubleTensor. Other Tensor types are useful if you want to save memory space.
Default Tensor type
For convenience, an alias torch.Tensor is provided, which allows the user to write type-independent scripts, which can then ran after choosing the desired Tensor type with a call like
torch.setdefaulttensortype('torch.FloatTensor')
See torch.setdefaulttensortype for more details. By default, the alias “points” on torch.DoubleTensor.
Efficient memory management
All tensor operations in this class do not make any memory copy. All these methods transform the existing tensor, or return a new tensor referencing the same storage. This magical behavior is internally obtained by good usage of the stride() and storageOffset(). Example:
> x = torch.Tensor(5):zero() > print(x) 0 0 0 0 0 [torch.DoubleTensor of dimension 5] > x:narrow(1, 2, 3):fill(1) -- narrow() returns a Tensor -- referencing the same Storage as x > print(x) 0 1 1 1 0 [torch.Tensor of dimension 5]
If you really need to copy a Tensor, you can use the copy() method:
> y = torch.Tensor(x:size()):copy(x)
Or the convenience method
> y = x:clone()
We now describe all the methods for Tensor. If you want to specify the Tensor type, just replace Tensor by the name of the Tensor variant (like CharTensor).
Tensor constructors, create new Tensor object, optionally, allocating new memory. By default the elements of a newly allocated memory are not initialized, therefore, might contain arbitrary numbers. Here are several ways to construct a new Tensor.
Returns an empty tensor.
Returns a new tensor which reference the same Storage than the given tensor. The size, stride, and storage offset are the same than the given tensor.
The new Tensor is now going to “view” the same storage as the given tensor. As a result, any modification in the elements of the Tensor will have a impact on the elements of the given tensor, and vice-versa. No memory copy!
> x = torch.Tensor(2,5):fill(3.14) > print(x) 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 [torch.DoubleTensor of dimension 2x5] > y = torch.Tensor(x) > print(y) 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 [torch.DoubleTensor of dimension 2x5] > y:zero() > print(x) -- elements of x are the same as y! 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 2x5]
Create a tensor up to 4 dimensions. The tensor size will be sz1 x sz2 x sx3 x sz4.
Create a tensor of any number of dimensions. The LongStorage sizes gives the size in each dimension of the tensor. The optional LongStorage strides gives the jump necessary to go from one element to the next one in the each dimension. Of course, sizes and strides must have the same number of elements. If not given, or if some elements of strides are negative, the stride() will be computed such that the tensor is as contiguous as possible in memory.
Example, create a 4D 4x4x3x2 tensor:
x = torch.Tensor(torch.LongStorage({4,4,3,2}))
Playing with the strides can give some interesting things:
x = torch.Tensor(torch.LongStorage({4}), torch.LongStorage({0})):zero() -- zeroes the tensor x[1] = 1 -- all elements point to the same address! print(x) 1 1 1 1 [torch.DoubleTensor of dimension 4]
Note that negative strides are not allowed, and, if given as argument when constructing the Tensor, will be interpreted as //choose the right stride such that the Tensor is contiguous in memory//.
Returns a tensor which uses the existing Storage storage, starting at position storageOffset (>=1). The size of each dimension of the tensor is given by the LongStorage sizes.
If only storage is provided, it will create a 1D Tensor viewing the all Storage.
The jump necessary to go from one element to the next one in each dimension is given by the optional argument LongStorage strides. If not given, or if some elements of strides are negative, the stride() will be computed such that the tensor is as contiguous as possible in memory.
Any modification in the elements of the Storage will have an impact on the elements of the new Tensor, and vice-versa. There is no memory copy!
-- creates a storage with 10 elements > s = torch.Storage(10):fill(1) -- we want to see it as a 2x5 tensor > x = torch.Tensor(s, 1, torch.LongStorage{2,5}) > print(x) 1 1 1 1 1 1 1 1 1 1 [torch.DoubleTensor of dimension 2x5] > x:zero() > print(s) -- the storage contents have been modified > print(s) 0 0 0 0 0 0 0 0 0 0 [torch.DoubleStorage of size 10]
Convenience constructor (for the previous constructor) assuming a number of dimensions inferior or equal to 4. szi is the size in the i-th dimension, and sti it the stride in the i-th dimension.
The argument is assumed to be a Lua array of numbers. The constructor returns a new Tensor of the size of the table, containing all the table elements. The table might be multi-dimensional.
Example:
> = torch.Tensor({{1,2,3,4}, {5,6,7,8}}) 1 2 3 4 5 6 7 8 [torch.DoubleTensor of dimension 2x4]
Returns a clone of a tensor. The memory is copied.
i = 0 x = torch.Tensor(5):apply(function(x) i = i + 1 return i end) = x 1 2 3 4 5 [torch.DoubleTensor of dimension 5] -- create a clone of x y = x:clone() = y 1 2 3 4 5 [torch.DoubleTensor of dimension 5] -- fill up y with 1 y:fill(1) = y 1 1 1 1 1 [torch.DoubleTensor of dimension 5] -- the contents of x were not changed: = x 1 2 3 4 5 [torch.DoubleTensor of dimension 5]
x = torch.Tensor(2,3):fill(1) = x 1 1 1 1 1 1 [torch.DoubleTensor of dimension 2x3] -- x is contiguous, so y points to the same thing y = x:contiguous():fill(2) = y 2 2 2 2 2 2 [torch.DoubleTensor of dimension 2x3] -- contents of x have been changed = x 2 2 2 2 2 2 [torch.DoubleTensor of dimension 2x3] -- x:t() is not contiguous, so z is a clone z = x:t():contiguous():fill(3.14) = z 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 [torch.DoubleTensor of dimension 3x2] -- contents of x have not been changed = x 2 2 2 2 2 2 [torch.DoubleTensor of dimension 2x3]
If type is nil, returns atring containing the type name of the given tensor.
= torch.Tensor():type() torch.DoubleTensor
If type is a string describing a Tensor type, and is equal to the given tensor typename, returns the exact same tensor (//no memory copy//).
x = torch.Tensor(3):fill(3.14) = x 3.1400 3.1400 3.1400 [torch.DoubleTensor of dimension 3] y = x:type('torch.DoubleTensor') = y 3.1400 3.1400 3.1400 [torch.DoubleTensor of dimension 3] -- zero y contents y:zero() -- contents of x have been changed = x 0 0 0 [torch.DoubleTensor of dimension 3]
If type is a string describing a Tensor type, different from the type name of the given Tensor, returns a new Tensor of the specified type, whose contents corresponds to the contents of the original Tensor, casted to the given type (//memory copy occurs, with possible loss of precision//).
x = torch.Tensor(3):fill(3.14) = x 3.1400 3.1400 3.1400 [torch.DoubleTensor of dimension 3] y = x:type('torch.IntTensor') = y 3 3 3 [torch.IntTensor of dimension 3]
Convenience method for the type method. Equivalent to
type(tensor:type())
Convenience methods for the type method. For e.g.,
x = torch.Tensor(3):fill(3.14) = x 3.1400 3.1400 3.1400 [torch.DoubleTensor of dimension 3] -- calling type('torch.IntTensor') = x:type('torch.IntTensor') 3 3 3 [torch.IntTensor of dimension 3] -- is equivalent to calling int() = x:int() 3 3 3 [torch.IntTensor of dimension 3]
Returns the number of dimensions in a Tensor.
> x = torch.Tensor(4,5) -- a matrix > = x:nDimension() 2
Same as nDimension().
Returns the size of the specified dimension dim. Example:
> x = torch.Tensor(4,5):zero() > print(x) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 4x5] > return x:size(2) -- gets the number of columns 5
Returns a LongStorage containing the size of each dimension of the tensor.
> x = torch.Tensor(4,5):zero() > print(x) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 4x5] > return x:size() 4 5 [torch.LongStorage of size 2]
Same as size() method.
Returns the jump necessary to go from one element to the next one in the specified dimension dim. Example:
> x = torch.Tensor(4,5):zero() > print(x) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 4x5] --- elements in a row are contiguous in memory > return x:stride(2) 1 --- to go from one element to the next one in a column --- we need here to jump the size of the row > return x:stride(1) 5
Note also that in Torch elements in the same row [elements along the last dimension] are contiguous in memory for a matrix [tensor].
Returns the jump necessary to go from one element to the next one in each dimension. Example:
> x = torch.Tensor(4,5):zero() > print(x) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 4x5] > return x:stride() 5 1 -- elements are contiguous in a row [last dimension] [torch.LongStorage of size 2]
Note also that in Torch elements in the same row [elements along the last dimension] are contiguous in memory for a matrix [tensor].
Returns the Storage used to store all the elements of the Tensor. Basically, a Tensor is a particular way of viewing a Storage.
> x = torch.Tensor(4,5) > s = x:storage() > for i=1,s:size() do -- fill up the Storage >> s[i] = i >> end > print(x) -- s is interpreted by x as a 2D matrix 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 [torch.DoubleTensor of dimension 4x5]
Returns true iff the elements of the Tensor are contiguous in memory.
-- normal tensors are contiguous in memory > x = torch.Tensor(4,5):zero() > = x:isContiguous() true -- y now "views" the 3rd column of x -- the storage of y is the same than x -- so the memory cannot be contiguous > y = x:select(2, 3) > = y:isContiguous() false -- indeed, to jump to one element to -- the next one, the stride is 4 > = y:stride() 5 [torch.LongStorage of size 1]
Returns the number of elements of a tensor.
> x = torch.Tensor(4,5) > = x:nElement() -- 4x5 = 20! 20
Return the first index (starting at 1) used in the tensor's storage.
Elements of a tensor can be retrieved with the [index] operator.
If index is a number, [index] operator is equivalent to a select(1, index) if the tensor has more than one dimension. If the tensor is a 1D tensor, it returns the value at index in this tensor.
If index is a table, the table must contain n numbers, where n is the number of dimensions of the Tensor. It will return the element at the given position.
In the same spirit, index might be a LongStorage, specifying the position (in the Tensor) of the element to be retrieved.
Example:
> x = torch.Tensor(3,3) > i = 0; x:apply(function() i = i + 1; return i end) > = x 1 2 3 4 5 6 7 8 9 [torch.DoubleTensor of dimension 3x3] > = x[2] -- returns row 2 4 5 6 [torch.DoubleTensor of dimension 3] > = x[2][3] -- returns row 2, column 3 6 > = x[{2,3}] -- another way to return row 2, column 3 6 > = x[torch.LongStorage{2,3}] -- yet another way to return row 2, column 3 6
A Tensor being a way of viewing a Storage, it is possible to “set” a Tensor such that it views an existing Storage.
Note that if you want to perform a set on an empty Tensor like
y = torch.Storage(10) x = torch.Tensor() x:set(y, 1, 10)
you might want in that case to use one of the equivalent constructor.
y = torch.Storage(10) x = torch.Tensor(y, 1, 10)
The Tensor is now going to “view” the same storage as the given tensor. As the result, any modification in the elements of the Tensor will have an impact on the elements of the given tensor, and vice-versa. This is an efficient method, as there is no memory copy!
> x = torch.Tensor(2,5):fill(3.14) > print(x) 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 [torch.DoubleTensor of dimension 2x5] > y = torch.Tensor():set(x) > print(y) 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 3.1400 [torch.DoubleTensor of dimension 2x5] > y:zero() > print(x) -- elements of x are the same than y! 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 2x5]
The Tensor is now going to “view” the given storage, starting at position storageOffset (>=1) with the given dimension sizes and the optional given strides. As the result, any modification in the elements of the Storage will have a impact on the elements of the Tensor, and vice-versa. This is an efficient method, as there is no memory copy!
If only storage is provided, the whole storage will be viewed as a 1D Tensor.
-- creates a storage with 10 elements > s = torch.Storage(10):fill(1) -- we want to see it as a 2x5 tensor > sz = torch.LongStorage({2,5}) > x = torch.Tensor() > x:set(s, 1, sz) > print(x) 1 1 1 1 1 1 1 1 1 1 [torch.DoubleTensor of dimension 2x5] > x:zero() > print(s) -- the storage contents have been modified > print(s) 0 0 0 0 0 0 0 0 0 0 [torch.DoubleStorage of size 10]
This is a “shorcut” for previous method. It works up to 4 dimensions. szi is the size of the i-th dimension of the tensor. sti is the stride in the i-th dimension.
Copy the elements of the given tensor. The number of elements must match, but the sizes might be different.
> x = torch.Tensor(4):fill(1) > y = torch.Tensor(2,2):copy(x) > print(x) 1 1 1 1 [torch.DoubleTensor of dimension 4] > print(y) 1 1 1 1 [torch.DoubleTensor of dimension 2x2]
If a different type of tensor is given, then a type conversion occurs, which, of course, might result in loss of precision.
Fill the tensor with the given value.
> = torch.DoubleTensor(4):fill(3.14) 3.1400 3.1400 3.1400 3.1400 [torch.DoubleTensor of dimension 4]
Fill the tensor with zeros.
> = torch.Tensor(4):zero() 0 0 0 0 [torch.DoubleTensor of dimension 4]
When resizing to a larger size, the underlying Storage is resized to fit all the elements of the Tensor.
When resizing to a smaller size, the underlying Storage is not resized.
Important note: the content of a Tensor after resizing is undertermined as strides might have been completely changed. In particular, the elements of the resized tensor are contiguous in memory.
Resize the tensor as the given tensor (of the same type).
Resize the tensor according to the given LongStorage size.
Convenience method of the previous method, working for a number of dimensions up to 4.
Each of these methods returns a Tensor which is a sub-tensor of the given tensor, with the same Storage. Hence, any modification in the memory of the sub-tensor will have an impact on the primary tensor, and vice-versa.
These methods are very fast, as they do not involve any memory copy.
Returns a new Tensor which is a narrowed version of the current one: the dimension dim is narrowed from index to index+size-1.
> x = torch.Tensor(5, 6):zero() > print(x) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 5x6] > y = x:narrow(1, 2, 3) -- narrow dimension 1 from index 2 to index 2+3-1 > y:fill(1) -- fill with 1 > print(y) 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 [torch.DoubleTensor of dimension 3x6] > print(x) -- memory in x has been modified! 0 0 0 0 0 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 0 0 0 0 0 [torch.DoubleTensor of dimension 5x6]
This method is equivalent to do a series of narrow up to the first 4 dimensions. It returns a new Tensor which is a sub-tensor going from index dimis to dimie in the i-th dimension. Negative values are interpreted index starting from the end: -1 is the last index, -2 is the index before the last index, ...
> x = torch.Tensor(5, 6):zero() > print(x) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 5x6] > y = x:sub(2,4):fill(1) -- y is sub-tensor of x: > print(y) -- dimension 1 starts at index 2, ends at index 4 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 [torch.DoubleTensor of dimension 3x6] > print(x) -- x has been modified! 0 0 0 0 0 0 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 0 0 0 0 0 [torch.DoubleTensor of dimension 5x6] > z = x:sub(2,4,3,4):fill(2) -- we now take a new sub-tensor > print(z) -- dimension 1 starts at index 2, ends at index 4 -- dimension 2 starts at index 3, ends at index 4 2 2 2 2 2 2 [torch.DoubleTensor of dimension 3x2] > print(x) -- x has been modified 0 0 0 0 0 0 1 1 2 2 1 1 1 1 2 2 1 1 1 1 2 2 1 1 0 0 0 0 0 0 [torch.DoubleTensor of dimension 5x6] > print(y:sub(-1, -1, 3, 4)) -- negative values = bounds 2 2 [torch.DoubleTensor of dimension 1x2]
Returns a new Tensor which is a tensor slice at the given index in the dimension dim. The returned tensor has one less dimension: the dimension dim is removed. As a result, it is not possible to select() on a 1D tensor.
Note that “selecting” on the first dimension is equivalent to use the [] operator
> x = torch.Tensor(5,6):zero() > print(x) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 5x6] > y = x:select(1, 2):fill(2) -- select row 2 and fill up > print(y) 2 2 2 2 2 2 [torch.DoubleTensor of dimension 6] > print(x) 0 0 0 0 0 0 2 2 2 2 2 2 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 5x6] > z = x:select(2,5):fill(5) -- select column 5 and fill up > print(z) 5 5 5 5 5 [torch.DoubleTensor of dimension 5] > print(x) 0 0 0 0 5 0 2 2 2 2 5 2 0 0 0 0 5 0 0 0 0 0 5 0 0 0 0 0 5 0 [torch.DoubleTensor of dimension 5x6]
The indexing operator [] can be used to combine narrow/sub and select in a concise an efficient way. It can also be used to copy, and fill (sub) tensors.
> x = torch.Tensor(5, 6):zero() > print(x) 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 5x6] > x[{ 1,3 }] = 1 -- sets element at (i=1,j=3) to 1 > print(x) 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 5x6] > x[{ 2,{2,4} }] = 2 -- sets a slice of 3 elements to 2 > print(x) 0 0 1 0 0 0 0 2 2 2 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 [torch.DoubleTensor of dimension 5x6] > x[{ {},4 }] = -1 -- sets the full 4th column to -1 > print(x) 0 0 1 -1 0 0 0 2 2 -1 0 0 0 0 0 -1 0 0 0 0 0 -1 0 0 0 0 0 -1 0 0 [torch.DoubleTensor of dimension 5x6] > x[{ {},2 }] = torch.range(1,5) -- copy a 1D tensor to a slice of x > print(x) 0 1 1 -1 0 0 0 2 2 -1 0 0 0 3 0 -1 0 0 0 4 0 -1 0 0 0 5 0 -1 0 0 [torch.DoubleTensor of dimension 5x6]
Returns a new Tensor which indexes the given tensor along dimension dim and using the entries in torch.LongTensor index. The returned tensor has the same number of dimensions as the original tensor. The returned tensor does not use the same storage as the original tensor.
t7> x = torch.rand(5,5) t7> =x 0.8020 0.7246 0.1204 0.3419 0.4385 0.0369 0.4158 0.0985 0.3024 0.8186 0.2746 0.9362 0.2546 0.8586 0.6674 0.7473 0.9028 0.1046 0.9085 0.6622 0.1412 0.6784 0.1624 0.8113 0.3949 [torch.DoubleTensor of dimension 5x5] t7> y = x:index(1,torch.LongTensor{3,1}) t7> =y 0.2746 0.9362 0.2546 0.8586 0.6674 0.8020 0.7246 0.1204 0.3419 0.4385 [torch.DoubleTensor of dimension 2x5] t7> y:fill(1) t7> =y 1 1 1 1 1 1 1 1 1 1 [torch.DoubleTensor of dimension 2x5] t7> =x 0.8020 0.7246 0.1204 0.3419 0.4385 0.0369 0.4158 0.0985 0.3024 0.8186 0.2746 0.9362 0.2546 0.8586 0.6674 0.7473 0.9028 0.1046 0.9085 0.6622 0.1412 0.6784 0.1624 0.8113 0.3949 [torch.DoubleTensor of dimension 5x5]
Note the explicit index function is different than the indexing operator []. The indexing operator [] is a syntactic shortcut for a series of select and narrow operations, therefore it always returns a new view on the original tensor that shares the same storage. However, he explicit index function can not use the same storage.
Copies the elements of tensor into itself by selecting the indices in the order defined by the order given in index.
t7> =x 0.8020 0.7246 0.1204 0.3419 0.4385 0.0369 0.4158 0.0985 0.3024 0.8186 0.2746 0.9362 0.2546 0.8586 0.6674 0.7473 0.9028 0.1046 0.9085 0.6622 0.1412 0.6784 0.1624 0.8113 0.3949 [torch.DoubleTensor of dimension 5x5] t7> z=torch.Tensor(5,2) t7> z:select(2,1):fill(-1) t7> z:select(2,2):fill(-2) t7> =z -1 -2 -1 -2 -1 -2 -1 -2 -1 -2 [torch.DoubleTensor of dimension 5x2] t7> x:indexCopy(2,torch.LongTensor{5,1},z) t7> =x -2.0000 0.7246 0.1204 0.3419 -1.0000 -2.0000 0.4158 0.0985 0.3024 -1.0000 -2.0000 0.9362 0.2546 0.8586 -1.0000 -2.0000 0.9028 0.1046 0.9085 -1.0000 -2.0000 0.6784 0.1624 0.8113 -1.0000 [torch.DoubleTensor of dimension 5x5]
Fills the elements of itself with value val by selecting the indices in the order defined by the order given in index.
t7> x=torch.rand(5,5) t7> =x 0.8414 0.4121 0.3934 0.5600 0.5403 0.3029 0.2040 0.7893 0.6079 0.6334 0.3743 0.1389 0.1573 0.1357 0.8460 0.2838 0.9925 0.0076 0.7220 0.5185 0.8739 0.6887 0.4271 0.0385 0.9116 [torch.DoubleTensor of dimension 5x5] t7> x:indexFill(2,torch.LongTensor{4,2},-10) t7> =x 0.8414 -10.0000 0.3934 -10.0000 0.5403 0.3029 -10.0000 0.7893 -10.0000 0.6334 0.3743 -10.0000 0.1573 -10.0000 0.8460 0.2838 -10.0000 0.0076 -10.0000 0.5185 0.8739 -10.0000 0.4271 -10.0000 0.9116 [torch.DoubleTensor of dimension 5x5]
These methods returns a Tensor which is created by replications of the original tensor.
sizes can either be a torch.LongStorage or numbers. Expanding a tensor does not allocate new memory, but only creates a new view on the existing tensor where singleton dimensions can be expanded to multiple ones by setting the stride to 0. Any dimension that is 1 can be expanded to arbitrary value without any new memory allocation.
t7> x=torch.rand(10,1) t7> =x 0.3837 0.5966 0.0763 0.1896 0.4958 0.6841 0.4038 0.4068 0.1502 0.2239 [torch.DoubleTensor of dimension 10x1] t7> y=torch.expand(x,10,2) t7> =y 0.3837 0.3837 0.5966 0.5966 0.0763 0.0763 0.1896 0.1896 0.4958 0.4958 0.6841 0.6841 0.4038 0.4038 0.4068 0.4068 0.1502 0.1502 0.2239 0.2239 [torch.DoubleTensor of dimension 10x2] t7> y:fill(1) t7> =y 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 [torch.DoubleTensor of dimension 10x2] t7> =x 1 1 1 1 1 1 1 1 1 1 [torch.DoubleTensor of dimension 10x1] t7> i=0; y:apply(function() i=i+1;return i end) t7> =y 2 2 4 4 6 6 8 8 10 10 12 12 14 14 16 16 18 18 20 20 [torch.DoubleTensor of dimension 10x2] t7> =x 2 4 6 8 10 12 14 16 18 20 [torch.DoubleTensor of dimension 10x1]
This is equivalent to self:expand(tensor:size())
sizes can either be a torch.LongStorage or numbers. Repeating a tensor allocates new memory. sizes specify the number of times the tensor is repeated in each dimension.
t7> x=torch.rand(5) t7> =x 0.7160 0.6514 0.0704 0.7856 0.7452 [torch.DoubleTensor of dimension 5] t7> =torch.repeatTensor(x,3,2) 0.7160 0.6514 0.0704 0.7856 0.7452 0.7160 0.6514 0.0704 0.7856 0.7452 0.7160 0.6514 0.0704 0.7856 0.7452 0.7160 0.6514 0.0704 0.7856 0.7452 0.7160 0.6514 0.0704 0.7856 0.7452 0.7160 0.6514 0.0704 0.7856 0.7452 [torch.DoubleTensor of dimension 3x10] t7> return torch.repeatTensor(x,3,2,1) (1,.,.) = 0.7160 0.6514 0.0704 0.7856 0.7452 0.7160 0.6514 0.0704 0.7856 0.7452 (2,.,.) = 0.7160 0.6514 0.0704 0.7856 0.7452 0.7160 0.6514 0.0704 0.7856 0.7452 (3,.,.) = 0.7160 0.6514 0.0704 0.7856 0.7452 0.7160 0.6514 0.0704 0.7856 0.7452 [torch.DoubleTensor of dimension 3x2x5]
Each of these methods returns a Tensor which is another way of viewing the Storage of the given tensor. Hence, any modification in the memory of the sub-tensor will have an impact on the primary tensor, and vice-versa.
These methods are very fast, are they do not involve any memory copy.
Returns a tensor where dimensions dim1 and dim2 have been swapped. For 2D tensors, the convenience method of t() is available.
> x = torch.Tensor(3,4):zero() > x:select(2,3):fill(7) -- fill column 3 with 7 > print(x) 0 0 7 0 0 0 7 0 0 0 7 0 [torch.DoubleTensor of dimension 3x4] > y = x:transpose(1,2) -- swap dimension 1 and 2 > print(y) 0 0 0 0 0 0 7 7 7 0 0 0 [torch.DoubleTensor of dimension 4x3] > y:select(2, 3):fill(8) -- fill column 3 with 8 > print(y) 0 0 8 0 0 8 7 7 8 0 0 8 [torch.DoubleTensor of dimension 4x3] > print(x) -- contents of x have changed as well 0 0 7 0 0 0 7 0 8 8 8 8 [torch.DoubleTensor of dimension 3x4]
Convenience method of transpose() for 2D tensors. The given tensor must be 2 dimensional. Swap dimensions 1 and 2.
> x = torch.Tensor(3,4):zero() > x:select(2,3):fill(7) > y = x:t() > print(y) 0 0 0 0 0 0 7 7 7 0 0 0 [torch.DoubleTensor of dimension 4x3] > print(x) 0 0 7 0 0 0 7 0 0 0 7 0 [torch.DoubleTensor of dimension 3x4]
Returns a tensor which contains all slices of size size in the dimension dim. Step between two slices is given by step.
If sizedim is the original size of dimension dim, the size of dimension dim in the returned tensor will be (sizedim - size) / step + 1
An additional dimension of size size is appended in the returned tensor.
> x = torch.Tensor(7) > for i=1,7 do x[i] = i end > print(x) 1 2 3 4 5 6 7 [torch.DoubleTensor of dimension 7] > return x:unfold(1, 2, 1) 1 2 2 3 3 4 4 5 5 6 6 7 [torch.DoubleTensor of dimension 6x2] > return x:unfold(1, 2, 2) 1 2 3 4 5 6 [torch.DoubleTensor of dimension 3x2]
These functions apply a function to each element of the tensor on which the method is called (self). These methods are much faster than using a for loop in Lua. The results is stored in self (if the function returns something).
Apply the given function to all elements of self.
The function takes a number (the current element of the tensor) and might return a number, in which case it will be stored in self.
Examples:
> i = 0 > z = torch.Tensor(3,3) > z:apply(function(x) >> i = i + 1 >> return i >> end) -- fill up the tensor > = z 1 2 3 4 5 6 7 8 9 [torch.DoubleTensor of dimension 3x3] > z:apply(math.sin) -- apply the sin function > = z 0.8415 0.9093 0.1411 -0.7568 -0.9589 -0.2794 0.6570 0.9894 0.4121 [torch.DoubleTensor of dimension 3x3] > sum = 0 > z:apply(function(x) >> sum = sum + x >> end) -- compute the sum of the elements > = sum 1.9552094821074 > = z:sum() -- it is indeed correct! 1.9552094821074
Apply the given function to all elements of self and tensor. The number of elements of both tensors must match, but sizes do not matter.
The function takes two numbers (the current element of self and tensor) and might return a number, in which case it will be stored in self.
Example:
> x = torch.Tensor(3,3) > y = torch.Tensor(9) > i = 0 > x:apply(function() i = i + 1; return i end) -- fill-up x > i = 0 > y:apply(function() i = i + 1; return i end) -- fill-up y > = x 1 2 3 4 5 6 7 8 9 [torch.DoubleTensor of dimension 3x3] > = y 1 2 3 4 5 6 7 8 9 [torch.DoubleTensor of dimension 9] > x:map(y, function(xx, yy) return xx*yy end) -- element-wise multiplication > = x 1 4 9 16 25 36 49 64 81 [torch.DoubleTensor of dimension 3x3]
Apply the given function to all elements of self, tensor1 and tensor2. The number of elements of all tensors must match, but sizes do not matter.
The function takes three numbers (the current element of self, tensor1 and tensor2) and might return a number, in which case it will be stored in self.
Example:
> x = torch.Tensor(3,3) > y = torch.Tensor(9) > z = torch.Tensor(3,3) > > i = 0; x:apply(function() i = i + 1; return math.cos(i)*math.cos(i) end) > i = 0; y:apply(function() i = i + 1; return i end) > i = 0; z:apply(function() i = i + 1; return i end) > > print(x) 0.2919 0.1732 0.9801 0.4272 0.0805 0.9219 0.5684 0.0212 0.8302 [torch.DoubleTensor of dimension 3x3] > print(y) 1 2 3 4 5 6 7 8 9 [torch.DoubleTensor of dimension 9] > print(z) 1 2 3 4 5 6 7 8 9 [torch.DoubleTensor of dimension 3x3] > > x:map2(y, z, function(xx, yy, zz) return xx+yy*zz end) > > print(x) 1.2919 4.1732 9.9801 16.4272 25.0805 36.9219 49.5684 64.0212 81.8302 [torch.DoubleTensor of dimension 3x3]