572 lines
25 KiB
Python
572 lines
25 KiB
Python
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from enum import Enum, auto
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import torch
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from torch import Tensor
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from ..utils import parametrize
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from ..modules import Module
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from .. import functional as F
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from typing import Optional
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__all__ = ['orthogonal', 'spectral_norm', 'weight_norm']
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def _is_orthogonal(Q, eps=None):
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n, k = Q.size(-2), Q.size(-1)
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Id = torch.eye(k, dtype=Q.dtype, device=Q.device)
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# A reasonable eps, but not too large
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eps = 10. * n * torch.finfo(Q.dtype).eps
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return torch.allclose(Q.mH @ Q, Id, atol=eps)
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def _make_orthogonal(A):
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"""Assume that A is a tall matrix.
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Compute the Q factor s.t. A = QR (A may be complex) and diag(R) is real and non-negative.
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"""
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X, tau = torch.geqrf(A)
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Q = torch.linalg.householder_product(X, tau)
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# The diagonal of X is the diagonal of R (which is always real) so we normalise by its signs
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Q *= X.diagonal(dim1=-2, dim2=-1).sgn().unsqueeze(-2)
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return Q
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class _OrthMaps(Enum):
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matrix_exp = auto()
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cayley = auto()
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householder = auto()
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class _Orthogonal(Module):
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base: Tensor
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def __init__(self,
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weight,
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orthogonal_map: _OrthMaps,
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*,
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use_trivialization=True) -> None:
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super().__init__()
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# Note [Householder complex]
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# For complex tensors, it is not possible to compute the tensor `tau` necessary for
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# linalg.householder_product from the reflectors.
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# To see this, note that the reflectors have a shape like:
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# 0 0 0
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# * 0 0
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# * * 0
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# which, for complex matrices, give n(n-1) (real) parameters. Now, you need n^2 parameters
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# to parametrize the unitary matrices. Saving tau on its own does not work either, because
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# not every combination of `(A, tau)` gives a unitary matrix, meaning that if we optimise
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# them as independent tensors we would not maintain the constraint
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# An equivalent reasoning holds for rectangular matrices
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if weight.is_complex() and orthogonal_map == _OrthMaps.householder:
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raise ValueError("The householder parametrization does not support complex tensors.")
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self.shape = weight.shape
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self.orthogonal_map = orthogonal_map
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if use_trivialization:
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self.register_buffer("base", None)
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def forward(self, X: torch.Tensor) -> torch.Tensor:
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n, k = X.size(-2), X.size(-1)
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transposed = n < k
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if transposed:
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X = X.mT
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n, k = k, n
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# Here n > k and X is a tall matrix
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if self.orthogonal_map == _OrthMaps.matrix_exp or self.orthogonal_map == _OrthMaps.cayley:
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# We just need n x k - k(k-1)/2 parameters
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X = X.tril()
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if n != k:
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# Embed into a square matrix
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X = torch.cat([X, X.new_zeros(n, n - k).expand(*X.shape[:-2], -1, -1)], dim=-1)
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A = X - X.mH
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# A is skew-symmetric (or skew-hermitian)
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if self.orthogonal_map == _OrthMaps.matrix_exp:
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Q = torch.matrix_exp(A)
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elif self.orthogonal_map == _OrthMaps.cayley:
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# Computes the Cayley retraction (I+A/2)(I-A/2)^{-1}
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Id = torch.eye(n, dtype=A.dtype, device=A.device)
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Q = torch.linalg.solve(torch.add(Id, A, alpha=-0.5), torch.add(Id, A, alpha=0.5))
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# Q is now orthogonal (or unitary) of size (..., n, n)
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if n != k:
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Q = Q[..., :k]
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# Q is now the size of the X (albeit perhaps transposed)
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else:
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# X is real here, as we do not support householder with complex numbers
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A = X.tril(diagonal=-1)
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tau = 2. / (1. + (A * A).sum(dim=-2))
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Q = torch.linalg.householder_product(A, tau)
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# The diagonal of X is 1's and -1's
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# We do not want to differentiate through this or update the diagonal of X hence the casting
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Q = Q * X.diagonal(dim1=-2, dim2=-1).int().unsqueeze(-2)
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if hasattr(self, "base"):
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Q = self.base @ Q
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if transposed:
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Q = Q.mT
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return Q # type: ignore[possibly-undefined]
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@torch.autograd.no_grad()
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def right_inverse(self, Q: torch.Tensor) -> torch.Tensor:
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if Q.shape != self.shape:
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raise ValueError(f"Expected a matrix or batch of matrices of shape {self.shape}. "
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f"Got a tensor of shape {Q.shape}.")
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Q_init = Q
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n, k = Q.size(-2), Q.size(-1)
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transpose = n < k
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if transpose:
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Q = Q.mT
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n, k = k, n
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# We always make sure to always copy Q in every path
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if not hasattr(self, "base"):
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# Note [right_inverse expm cayley]
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# If we do not have use_trivialization=True, we just implement the inverse of the forward
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# map for the Householder. To see why, think that for the Cayley map,
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# we would need to find the matrix X \in R^{n x k} such that:
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# Y = torch.cat([X.tril(), X.new_zeros(n, n - k).expand(*X.shape[:-2], -1, -1)], dim=-1)
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# A = Y - Y.mH
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# cayley(A)[:, :k]
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# gives the original tensor. It is not clear how to do this.
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# Perhaps via some algebraic manipulation involving the QR like that of
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# Corollary 2.2 in Edelman, Arias and Smith?
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if self.orthogonal_map == _OrthMaps.cayley or self.orthogonal_map == _OrthMaps.matrix_exp:
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raise NotImplementedError("It is not possible to assign to the matrix exponential "
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"or the Cayley parametrizations when use_trivialization=False.")
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# If parametrization == _OrthMaps.householder, make Q orthogonal via the QR decomposition.
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# Here Q is always real because we do not support householder and complex matrices.
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# See note [Householder complex]
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A, tau = torch.geqrf(Q)
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# We want to have a decomposition X = QR with diag(R) > 0, as otherwise we could
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# decompose an orthogonal matrix Q as Q = (-Q)@(-Id), which is a valid QR decomposition
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# The diagonal of Q is the diagonal of R from the qr decomposition
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A.diagonal(dim1=-2, dim2=-1).sign_()
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# Equality with zero is ok because LAPACK returns exactly zero when it does not want
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# to use a particular reflection
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A.diagonal(dim1=-2, dim2=-1)[tau == 0.] *= -1
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return A.mT if transpose else A
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else:
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if n == k:
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# We check whether Q is orthogonal
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if not _is_orthogonal(Q):
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Q = _make_orthogonal(Q)
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else: # Is orthogonal
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Q = Q.clone()
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else:
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# Complete Q into a full n x n orthogonal matrix
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N = torch.randn(*(Q.size()[:-2] + (n, n - k)), dtype=Q.dtype, device=Q.device)
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Q = torch.cat([Q, N], dim=-1)
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Q = _make_orthogonal(Q)
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self.base = Q
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# It is necessary to return the -Id, as we use the diagonal for the
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# Householder parametrization. Using -Id makes:
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# householder(torch.zeros(m,n)) == torch.eye(m,n)
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# Poor man's version of eye_like
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neg_Id = torch.zeros_like(Q_init)
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neg_Id.diagonal(dim1=-2, dim2=-1).fill_(-1.)
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return neg_Id
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def orthogonal(module: Module,
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name: str = 'weight',
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orthogonal_map: Optional[str] = None,
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*,
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use_trivialization: bool = True) -> Module:
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r"""Apply an orthogonal or unitary parametrization to a matrix or a batch of matrices.
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Letting :math:`\mathbb{K}` be :math:`\mathbb{R}` or :math:`\mathbb{C}`, the parametrized
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matrix :math:`Q \in \mathbb{K}^{m \times n}` is **orthogonal** as
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.. math::
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\begin{align*}
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Q^{\text{H}}Q &= \mathrm{I}_n \mathrlap{\qquad \text{if }m \geq n}\\
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QQ^{\text{H}} &= \mathrm{I}_m \mathrlap{\qquad \text{if }m < n}
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\end{align*}
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where :math:`Q^{\text{H}}` is the conjugate transpose when :math:`Q` is complex
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and the transpose when :math:`Q` is real-valued, and
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:math:`\mathrm{I}_n` is the `n`-dimensional identity matrix.
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In plain words, :math:`Q` will have orthonormal columns whenever :math:`m \geq n`
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and orthonormal rows otherwise.
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If the tensor has more than two dimensions, we consider it as a batch of matrices of shape `(..., m, n)`.
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The matrix :math:`Q` may be parametrized via three different ``orthogonal_map`` in terms of the original tensor:
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- ``"matrix_exp"``/``"cayley"``:
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the :func:`~torch.matrix_exp` :math:`Q = \exp(A)` and the `Cayley map`_
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:math:`Q = (\mathrm{I}_n + A/2)(\mathrm{I}_n - A/2)^{-1}` are applied to a skew-symmetric
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:math:`A` to give an orthogonal matrix.
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- ``"householder"``: computes a product of Householder reflectors
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(:func:`~torch.linalg.householder_product`).
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``"matrix_exp"``/``"cayley"`` often make the parametrized weight converge faster than
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``"householder"``, but they are slower to compute for very thin or very wide matrices.
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If ``use_trivialization=True`` (default), the parametrization implements the "Dynamic Trivialization Framework",
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where an extra matrix :math:`B \in \mathbb{K}^{n \times n}` is stored under
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``module.parametrizations.weight[0].base``. This helps the
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convergence of the parametrized layer at the expense of some extra memory use.
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See `Trivializations for Gradient-Based Optimization on Manifolds`_ .
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Initial value of :math:`Q`:
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If the original tensor is not parametrized and ``use_trivialization=True`` (default), the initial value
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of :math:`Q` is that of the original tensor if it is orthogonal (or unitary in the complex case)
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and it is orthogonalized via the QR decomposition otherwise (see :func:`torch.linalg.qr`).
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Same happens when it is not parametrized and ``orthogonal_map="householder"`` even when ``use_trivialization=False``.
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Otherwise, the initial value is the result of the composition of all the registered
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parametrizations applied to the original tensor.
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.. note::
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This function is implemented using the parametrization functionality
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in :func:`~torch.nn.utils.parametrize.register_parametrization`.
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.. _`Cayley map`: https://en.wikipedia.org/wiki/Cayley_transform#Matrix_map
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.. _`Trivializations for Gradient-Based Optimization on Manifolds`: https://arxiv.org/abs/1909.09501
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Args:
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module (nn.Module): module on which to register the parametrization.
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name (str, optional): name of the tensor to make orthogonal. Default: ``"weight"``.
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orthogonal_map (str, optional): One of the following: ``"matrix_exp"``, ``"cayley"``, ``"householder"``.
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Default: ``"matrix_exp"`` if the matrix is square or complex, ``"householder"`` otherwise.
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use_trivialization (bool, optional): whether to use the dynamic trivialization framework.
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Default: ``True``.
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Returns:
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The original module with an orthogonal parametrization registered to the specified
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weight
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Example::
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>>> # xdoctest: +REQUIRES(env:TORCH_DOCTEST_LAPACK)
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>>> orth_linear = orthogonal(nn.Linear(20, 40))
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>>> orth_linear
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ParametrizedLinear(
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in_features=20, out_features=40, bias=True
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(parametrizations): ModuleDict(
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(weight): ParametrizationList(
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(0): _Orthogonal()
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)
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)
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)
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>>> # xdoctest: +IGNORE_WANT
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>>> Q = orth_linear.weight
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>>> torch.dist(Q.T @ Q, torch.eye(20))
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tensor(4.9332e-07)
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"""
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weight = getattr(module, name, None)
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if not isinstance(weight, Tensor):
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raise ValueError(
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f"Module '{module}' has no parameter or buffer with name '{name}'"
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)
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# We could implement this for 1-dim tensors as the maps on the sphere
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# but I believe it'd bite more people than it'd help
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if weight.ndim < 2:
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raise ValueError("Expected a matrix or batch of matrices. "
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f"Got a tensor of {weight.ndim} dimensions.")
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if orthogonal_map is None:
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orthogonal_map = "matrix_exp" if weight.size(-2) == weight.size(-1) or weight.is_complex() else "householder"
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orth_enum = getattr(_OrthMaps, orthogonal_map, None)
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if orth_enum is None:
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raise ValueError('orthogonal_map has to be one of "matrix_exp", "cayley", "householder". '
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f'Got: {orthogonal_map}')
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orth = _Orthogonal(weight,
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orth_enum,
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use_trivialization=use_trivialization)
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parametrize.register_parametrization(module, name, orth, unsafe=True)
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return module
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class _WeightNorm(Module):
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def __init__(
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self,
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dim: Optional[int] = 0,
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) -> None:
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super().__init__()
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if dim is None:
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dim = -1
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self.dim = dim
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def forward(self, weight_g, weight_v):
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return torch._weight_norm(weight_v, weight_g, self.dim)
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def right_inverse(self, weight):
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weight_g = torch.norm_except_dim(weight, 2, self.dim)
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weight_v = weight
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return weight_g, weight_v
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def weight_norm(module: Module, name: str = 'weight', dim: int = 0):
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r"""Apply weight normalization to a parameter in the given module.
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.. math::
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\mathbf{w} = g \dfrac{\mathbf{v}}{\|\mathbf{v}\|}
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Weight normalization is a reparameterization that decouples the magnitude
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of a weight tensor from its direction. This replaces the parameter specified
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by :attr:`name` with two parameters: one specifying the magnitude
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and one specifying the direction.
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By default, with ``dim=0``, the norm is computed independently per output
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channel/plane. To compute a norm over the entire weight tensor, use
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``dim=None``.
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See https://arxiv.org/abs/1602.07868
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Args:
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module (Module): containing module
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name (str, optional): name of weight parameter
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dim (int, optional): dimension over which to compute the norm
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Returns:
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The original module with the weight norm hook
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Example::
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>>> m = weight_norm(nn.Linear(20, 40), name='weight')
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>>> m
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ParametrizedLinear(
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in_features=20, out_features=40, bias=True
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(parametrizations): ModuleDict(
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(weight): ParametrizationList(
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(0): _WeightNorm()
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)
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)
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)
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>>> m.parametrizations.weight.original0.size()
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torch.Size([40, 1])
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>>> m.parametrizations.weight.original1.size()
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torch.Size([40, 20])
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"""
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_weight_norm = _WeightNorm(dim)
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parametrize.register_parametrization(module, name, _weight_norm, unsafe=True)
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def _weight_norm_compat_hook(state_dict, prefix, local_metadata, strict, missing_keys, unexpected_keys, error_msgs):
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g_key = f"{prefix}{name}_g"
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v_key = f"{prefix}{name}_v"
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if g_key in state_dict and v_key in state_dict:
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original0 = state_dict.pop(g_key)
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original1 = state_dict.pop(v_key)
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state_dict[f"{prefix}parametrizations.{name}.original0"] = original0
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state_dict[f"{prefix}parametrizations.{name}.original1"] = original1
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module._register_load_state_dict_pre_hook(_weight_norm_compat_hook)
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return module
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class _SpectralNorm(Module):
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def __init__(
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self,
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weight: torch.Tensor,
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n_power_iterations: int = 1,
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dim: int = 0,
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eps: float = 1e-12
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) -> None:
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super().__init__()
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ndim = weight.ndim
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if dim >= ndim or dim < -ndim:
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raise IndexError("Dimension out of range (expected to be in range of "
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f"[-{ndim}, {ndim - 1}] but got {dim})")
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if n_power_iterations <= 0:
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raise ValueError('Expected n_power_iterations to be positive, but '
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f'got n_power_iterations={n_power_iterations}')
|
||
|
self.dim = dim if dim >= 0 else dim + ndim
|
||
|
self.eps = eps
|
||
|
if ndim > 1:
|
||
|
# For ndim == 1 we do not need to approximate anything (see _SpectralNorm.forward)
|
||
|
self.n_power_iterations = n_power_iterations
|
||
|
weight_mat = self._reshape_weight_to_matrix(weight)
|
||
|
h, w = weight_mat.size()
|
||
|
|
||
|
u = weight_mat.new_empty(h).normal_(0, 1)
|
||
|
v = weight_mat.new_empty(w).normal_(0, 1)
|
||
|
self.register_buffer('_u', F.normalize(u, dim=0, eps=self.eps))
|
||
|
self.register_buffer('_v', F.normalize(v, dim=0, eps=self.eps))
|
||
|
|
||
|
# Start with u, v initialized to some reasonable values by performing a number
|
||
|
# of iterations of the power method
|
||
|
self._power_method(weight_mat, 15)
|
||
|
|
||
|
def _reshape_weight_to_matrix(self, weight: torch.Tensor) -> torch.Tensor:
|
||
|
# Precondition
|
||
|
assert weight.ndim > 1
|
||
|
|
||
|
if self.dim != 0:
|
||
|
# permute dim to front
|
||
|
weight = weight.permute(self.dim, *(d for d in range(weight.dim()) if d != self.dim))
|
||
|
|
||
|
return weight.flatten(1)
|
||
|
|
||
|
@torch.autograd.no_grad()
|
||
|
def _power_method(self, weight_mat: torch.Tensor, n_power_iterations: int) -> None:
|
||
|
# See original note at torch/nn/utils/spectral_norm.py
|
||
|
# NB: If `do_power_iteration` is set, the `u` and `v` vectors are
|
||
|
# updated in power iteration **in-place**. This is very important
|
||
|
# because in `DataParallel` forward, the vectors (being buffers) are
|
||
|
# broadcast from the parallelized module to each module replica,
|
||
|
# which is a new module object created on the fly. And each replica
|
||
|
# runs its own spectral norm power iteration. So simply assigning
|
||
|
# the updated vectors to the module this function runs on will cause
|
||
|
# the update to be lost forever. And the next time the parallelized
|
||
|
# module is replicated, the same randomly initialized vectors are
|
||
|
# broadcast and used!
|
||
|
#
|
||
|
# Therefore, to make the change propagate back, we rely on two
|
||
|
# important behaviors (also enforced via tests):
|
||
|
# 1. `DataParallel` doesn't clone storage if the broadcast tensor
|
||
|
# is already on correct device; and it makes sure that the
|
||
|
# parallelized module is already on `device[0]`.
|
||
|
# 2. If the out tensor in `out=` kwarg has correct shape, it will
|
||
|
# just fill in the values.
|
||
|
# Therefore, since the same power iteration is performed on all
|
||
|
# devices, simply updating the tensors in-place will make sure that
|
||
|
# the module replica on `device[0]` will update the _u vector on the
|
||
|
# parallelized module (by shared storage).
|
||
|
#
|
||
|
# However, after we update `u` and `v` in-place, we need to **clone**
|
||
|
# them before using them to normalize the weight. This is to support
|
||
|
# backproping through two forward passes, e.g., the common pattern in
|
||
|
# GAN training: loss = D(real) - D(fake). Otherwise, engine will
|
||
|
# complain that variables needed to do backward for the first forward
|
||
|
# (i.e., the `u` and `v` vectors) are changed in the second forward.
|
||
|
|
||
|
# Precondition
|
||
|
assert weight_mat.ndim > 1
|
||
|
|
||
|
for _ in range(n_power_iterations):
|
||
|
# Spectral norm of weight equals to `u^T W v`, where `u` and `v`
|
||
|
# are the first left and right singular vectors.
|
||
|
# This power iteration produces approximations of `u` and `v`.
|
||
|
self._u = F.normalize(torch.mv(weight_mat, self._v), # type: ignore[has-type]
|
||
|
dim=0, eps=self.eps, out=self._u) # type: ignore[has-type]
|
||
|
self._v = F.normalize(torch.mv(weight_mat.H, self._u),
|
||
|
dim=0, eps=self.eps, out=self._v) # type: ignore[has-type]
|
||
|
|
||
|
def forward(self, weight: torch.Tensor) -> torch.Tensor:
|
||
|
if weight.ndim == 1:
|
||
|
# Faster and more exact path, no need to approximate anything
|
||
|
return F.normalize(weight, dim=0, eps=self.eps)
|
||
|
else:
|
||
|
weight_mat = self._reshape_weight_to_matrix(weight)
|
||
|
if self.training:
|
||
|
self._power_method(weight_mat, self.n_power_iterations)
|
||
|
# See above on why we need to clone
|
||
|
u = self._u.clone(memory_format=torch.contiguous_format)
|
||
|
v = self._v.clone(memory_format=torch.contiguous_format)
|
||
|
# The proper way of computing this should be through F.bilinear, but
|
||
|
# it seems to have some efficiency issues:
|
||
|
# https://github.com/pytorch/pytorch/issues/58093
|
||
|
sigma = torch.vdot(u, torch.mv(weight_mat, v))
|
||
|
return weight / sigma
|
||
|
|
||
|
def right_inverse(self, value: torch.Tensor) -> torch.Tensor:
|
||
|
# we may want to assert here that the passed value already
|
||
|
# satisfies constraints
|
||
|
return value
|
||
|
|
||
|
|
||
|
def spectral_norm(module: Module,
|
||
|
name: str = 'weight',
|
||
|
n_power_iterations: int = 1,
|
||
|
eps: float = 1e-12,
|
||
|
dim: Optional[int] = None) -> Module:
|
||
|
r"""Apply spectral normalization to a parameter in the given module.
|
||
|
|
||
|
.. math::
|
||
|
\mathbf{W}_{SN} = \dfrac{\mathbf{W}}{\sigma(\mathbf{W})},
|
||
|
\sigma(\mathbf{W}) = \max_{\mathbf{h}: \mathbf{h} \ne 0} \dfrac{\|\mathbf{W} \mathbf{h}\|_2}{\|\mathbf{h}\|_2}
|
||
|
|
||
|
When applied on a vector, it simplifies to
|
||
|
|
||
|
.. math::
|
||
|
\mathbf{x}_{SN} = \dfrac{\mathbf{x}}{\|\mathbf{x}\|_2}
|
||
|
|
||
|
Spectral normalization stabilizes the training of discriminators (critics)
|
||
|
in Generative Adversarial Networks (GANs) by reducing the Lipschitz constant
|
||
|
of the model. :math:`\sigma` is approximated performing one iteration of the
|
||
|
`power method`_ every time the weight is accessed. If the dimension of the
|
||
|
weight tensor is greater than 2, it is reshaped to 2D in power iteration
|
||
|
method to get spectral norm.
|
||
|
|
||
|
|
||
|
See `Spectral Normalization for Generative Adversarial Networks`_ .
|
||
|
|
||
|
.. _`power method`: https://en.wikipedia.org/wiki/Power_iteration
|
||
|
.. _`Spectral Normalization for Generative Adversarial Networks`: https://arxiv.org/abs/1802.05957
|
||
|
|
||
|
.. note::
|
||
|
This function is implemented using the parametrization functionality
|
||
|
in :func:`~torch.nn.utils.parametrize.register_parametrization`. It is a
|
||
|
reimplementation of :func:`torch.nn.utils.spectral_norm`.
|
||
|
|
||
|
.. note::
|
||
|
When this constraint is registered, the singular vectors associated to the largest
|
||
|
singular value are estimated rather than sampled at random. These are then updated
|
||
|
performing :attr:`n_power_iterations` of the `power method`_ whenever the tensor
|
||
|
is accessed with the module on `training` mode.
|
||
|
|
||
|
.. note::
|
||
|
If the `_SpectralNorm` module, i.e., `module.parametrization.weight[idx]`,
|
||
|
is in training mode on removal, it will perform another power iteration.
|
||
|
If you'd like to avoid this iteration, set the module to eval mode
|
||
|
before its removal.
|
||
|
|
||
|
Args:
|
||
|
module (nn.Module): containing module
|
||
|
name (str, optional): name of weight parameter. Default: ``"weight"``.
|
||
|
n_power_iterations (int, optional): number of power iterations to
|
||
|
calculate spectral norm. Default: ``1``.
|
||
|
eps (float, optional): epsilon for numerical stability in
|
||
|
calculating norms. Default: ``1e-12``.
|
||
|
dim (int, optional): dimension corresponding to number of outputs.
|
||
|
Default: ``0``, except for modules that are instances of
|
||
|
ConvTranspose{1,2,3}d, when it is ``1``
|
||
|
|
||
|
Returns:
|
||
|
The original module with a new parametrization registered to the specified
|
||
|
weight
|
||
|
|
||
|
Example::
|
||
|
|
||
|
>>> # xdoctest: +REQUIRES(env:TORCH_DOCTEST_LAPACK)
|
||
|
>>> # xdoctest: +IGNORE_WANT("non-deterministic")
|
||
|
>>> snm = spectral_norm(nn.Linear(20, 40))
|
||
|
>>> snm
|
||
|
ParametrizedLinear(
|
||
|
in_features=20, out_features=40, bias=True
|
||
|
(parametrizations): ModuleDict(
|
||
|
(weight): ParametrizationList(
|
||
|
(0): _SpectralNorm()
|
||
|
)
|
||
|
)
|
||
|
)
|
||
|
>>> torch.linalg.matrix_norm(snm.weight, 2)
|
||
|
tensor(1.0081, grad_fn=<AmaxBackward0>)
|
||
|
"""
|
||
|
weight = getattr(module, name, None)
|
||
|
if not isinstance(weight, Tensor):
|
||
|
raise ValueError(
|
||
|
f"Module '{module}' has no parameter or buffer with name '{name}'"
|
||
|
)
|
||
|
|
||
|
if dim is None:
|
||
|
if isinstance(module, (torch.nn.ConvTranspose1d,
|
||
|
torch.nn.ConvTranspose2d,
|
||
|
torch.nn.ConvTranspose3d)):
|
||
|
dim = 1
|
||
|
else:
|
||
|
dim = 0
|
||
|
parametrize.register_parametrization(module, name, _SpectralNorm(weight, n_power_iterations, dim, eps))
|
||
|
return module
|