165 lines
5.5 KiB
Python
165 lines
5.5 KiB
Python
"""Various linear algebra utility methods for internal use.
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"""
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from typing import Optional, Tuple
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import torch
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from torch import Tensor
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def is_sparse(A):
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"""Check if tensor A is a sparse tensor"""
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if isinstance(A, torch.Tensor):
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return A.layout == torch.sparse_coo
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error_str = "expected Tensor"
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if not torch.jit.is_scripting():
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error_str += f" but got {type(A)}"
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raise TypeError(error_str)
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def get_floating_dtype(A):
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"""Return the floating point dtype of tensor A.
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Integer types map to float32.
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"""
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dtype = A.dtype
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if dtype in (torch.float16, torch.float32, torch.float64):
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return dtype
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return torch.float32
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def matmul(A: Optional[Tensor], B: Tensor) -> Tensor:
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"""Multiply two matrices.
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If A is None, return B. A can be sparse or dense. B is always
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dense.
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"""
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if A is None:
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return B
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if is_sparse(A):
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return torch.sparse.mm(A, B)
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return torch.matmul(A, B)
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def conjugate(A):
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"""Return conjugate of tensor A.
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.. note:: If A's dtype is not complex, A is returned.
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"""
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if A.is_complex():
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return A.conj()
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return A
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def transpose(A):
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"""Return transpose of a matrix or batches of matrices."""
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ndim = len(A.shape)
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return A.transpose(ndim - 1, ndim - 2)
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def transjugate(A):
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"""Return transpose conjugate of a matrix or batches of matrices."""
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return conjugate(transpose(A))
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def bform(X: Tensor, A: Optional[Tensor], Y: Tensor) -> Tensor:
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"""Return bilinear form of matrices: :math:`X^T A Y`."""
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return matmul(transpose(X), matmul(A, Y))
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def qform(A: Optional[Tensor], S: Tensor):
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"""Return quadratic form :math:`S^T A S`."""
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return bform(S, A, S)
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def basis(A):
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"""Return orthogonal basis of A columns."""
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return torch.linalg.qr(A).Q
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def symeig(A: Tensor, largest: Optional[bool] = False) -> Tuple[Tensor, Tensor]:
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"""Return eigenpairs of A with specified ordering."""
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if largest is None:
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largest = False
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E, Z = torch.linalg.eigh(A, UPLO="U")
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# assuming that E is ordered
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if largest:
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E = torch.flip(E, dims=(-1,))
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Z = torch.flip(Z, dims=(-1,))
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return E, Z
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# These functions were deprecated and removed
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# This nice error message can be removed in version 1.13+
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def matrix_rank(input, tol=None, symmetric=False, *, out=None) -> Tensor:
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raise RuntimeError(
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"This function was deprecated since version 1.9 and is now removed.\n"
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"Please use the `torch.linalg.matrix_rank` function instead. "
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"The parameter 'symmetric' was renamed in `torch.linalg.matrix_rank()` to 'hermitian'."
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)
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def solve(input: Tensor, A: Tensor, *, out=None) -> Tuple[Tensor, Tensor]:
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raise RuntimeError(
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"This function was deprecated since version 1.9 and is now removed. "
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"`torch.solve` is deprecated in favor of `torch.linalg.solve`. "
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"`torch.linalg.solve` has its arguments reversed and does not return the LU factorization.\n\n"
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"To get the LU factorization see `torch.lu`, which can be used with `torch.lu_solve` or `torch.lu_unpack`.\n"
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"X = torch.solve(B, A).solution "
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"should be replaced with:\n"
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"X = torch.linalg.solve(A, B)"
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)
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def lstsq(input: Tensor, A: Tensor, *, out=None) -> Tuple[Tensor, Tensor]:
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raise RuntimeError(
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"This function was deprecated since version 1.9 and is now removed. "
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"`torch.lstsq` is deprecated in favor of `torch.linalg.lstsq`.\n"
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"`torch.linalg.lstsq` has reversed arguments and does not return the QR decomposition in "
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"the returned tuple (although it returns other information about the problem).\n\n"
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"To get the QR decomposition consider using `torch.linalg.qr`.\n\n"
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"The returned solution in `torch.lstsq` stored the residuals of the solution in the "
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"last m - n columns of the returned value whenever m > n. In torch.linalg.lstsq, "
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"the residuals are in the field 'residuals' of the returned named tuple.\n\n"
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"The unpacking of the solution, as in\n"
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"X, _ = torch.lstsq(B, A).solution[:A.size(1)]\n"
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"should be replaced with:\n"
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"X = torch.linalg.lstsq(A, B).solution"
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)
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def _symeig(
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input, eigenvectors=False, upper=True, *, out=None
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) -> Tuple[Tensor, Tensor]:
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raise RuntimeError(
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"This function was deprecated since version 1.9 and is now removed. "
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"The default behavior has changed from using the upper triangular portion of the matrix by default "
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"to using the lower triangular portion.\n\n"
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"L, _ = torch.symeig(A, upper=upper) "
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"should be replaced with:\n"
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"L = torch.linalg.eigvalsh(A, UPLO='U' if upper else 'L')\n\n"
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"and\n\n"
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"L, V = torch.symeig(A, eigenvectors=True) "
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"should be replaced with:\n"
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"L, V = torch.linalg.eigh(A, UPLO='U' if upper else 'L')"
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)
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def eig(
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self: Tensor, eigenvectors: bool = False, *, e=None, v=None
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) -> Tuple[Tensor, Tensor]:
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raise RuntimeError(
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"This function was deprecated since version 1.9 and is now removed. "
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"`torch.linalg.eig` returns complex tensors of dtype `cfloat` or `cdouble` rather than real tensors "
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"mimicking complex tensors.\n\n"
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"L, _ = torch.eig(A) "
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"should be replaced with:\n"
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"L_complex = torch.linalg.eigvals(A)\n\n"
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"and\n\n"
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"L, V = torch.eig(A, eigenvectors=True) "
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"should be replaced with:\n"
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"L_complex, V_complex = torch.linalg.eig(A)"
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)
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