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torch.baddbmm

torch.baddbmm(input, batch1, batch2, *, beta=1, alpha=1, out=None) → Tensor

Performs a batch matrix-matrix product of matrices in batch1 and batch2. input is added to the final result.

batch1 and batch2 must be 3-D tensors each containing the same number of matrices.

If batch1 is a (b×n×m)(b \times n \times m) tensor, batch2 is a (b×m×p)(b \times m \times p) tensor, then input must be broadcastable with a (b×n×p)(b \times n \times p) tensor and out will be a (b×n×p)(b \times n \times p) tensor. Both alpha and beta mean the same as the scaling factors used in torch.addbmm().

outi=β inputi+α (batch1i@batch2i)\text{out}_i = \beta\ \text{input}_i + \alpha\ (\text{batch1}_i \mathbin{@} \text{batch2}_i)

If beta is 0, then input will be ignored, and nan and inf in it will not be propagated.

For inputs of type FloatTensor or DoubleTensor, arguments beta and alpha must be real numbers, otherwise they should be integers.

This operator supports TensorFloat32.

Parameters
  • input (Tensor) – the tensor to be added

  • batch1 (Tensor) – the first batch of matrices to be multiplied

  • batch2 (Tensor) – the second batch of matrices to be multiplied

Keyword Arguments
  • beta (Number, optional) – multiplier for input (β\beta )

  • alpha (Number, optional) – multiplier for batch1@batch2\text{batch1} \mathbin{@} \text{batch2} (α\alpha )

  • out (Tensor, optional) – the output tensor.

Example:

>>> M = torch.randn(10, 3, 5)
>>> batch1 = torch.randn(10, 3, 4)
>>> batch2 = torch.randn(10, 4, 5)
>>> torch.baddbmm(M, batch1, batch2).size()
torch.Size([10, 3, 5])

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