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40576bceaf
This PR fixes #69466 and introduces some other minor changes. Tests are somewhat more involved because a reference implementation in `scipy` is not available; tests proceed differently for discrete and continuous distributions. For continuous distributions, we evaluate the gradient of the `log_prob` at the mode. Tests pass if the gradient is zero OR (the mode is at the boundary of the support of the distribution AND the `log_prob` decreases as we move away from the boundary to the interior of the support). For discrete distributions, the notion of a gradient is not well defined. We thus "look" ahead and behind one step (e.g. if the mode of a Poisson distribution is 9, we consider 8 and 10). If the step ahead/behind is still within the support of the distribution, we assert that the `log_prob` is smaller than at the mode. For one-hot encoded distributions (currently just `OneHotCategorical`), we evaluate the underlying mode (i.e. encoded as an integral tensor), "advance" by one label to get another sample that should have lower probability using `other = (mode + 1) % event_size` and re-encode as one-hot. The resultant `other` sample should have lower probability than the mode. Furthermore, Gamma, half Cauchy, and half normal distributions have their support changed from positive to nonnegative. This change is necessary because the mode of the "half" distributions is zero, and the mode of the gamma distribution is zero for `concentration <= 1`. cc @fritzo Pull Request resolved: https://github.com/pytorch/pytorch/pull/76690 Approved by: https://github.com/neerajprad
71 lines
2.5 KiB
Python
71 lines
2.5 KiB
Python
from numbers import Number
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import math
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import torch
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from torch.distributions import constraints
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from torch.distributions.uniform import Uniform
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from torch.distributions.transformed_distribution import TransformedDistribution
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from torch.distributions.transforms import AffineTransform, ExpTransform
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from torch.distributions.utils import broadcast_all, euler_constant
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class Gumbel(TransformedDistribution):
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r"""
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Samples from a Gumbel Distribution.
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Examples::
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>>> m = Gumbel(torch.tensor([1.0]), torch.tensor([2.0]))
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>>> m.sample() # sample from Gumbel distribution with loc=1, scale=2
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tensor([ 1.0124])
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Args:
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loc (float or Tensor): Location parameter of the distribution
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scale (float or Tensor): Scale parameter of the distribution
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"""
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arg_constraints = {'loc': constraints.real, 'scale': constraints.positive}
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support = constraints.real
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def __init__(self, loc, scale, validate_args=None):
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self.loc, self.scale = broadcast_all(loc, scale)
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finfo = torch.finfo(self.loc.dtype)
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if isinstance(loc, Number) and isinstance(scale, Number):
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base_dist = Uniform(finfo.tiny, 1 - finfo.eps)
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else:
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base_dist = Uniform(torch.full_like(self.loc, finfo.tiny),
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torch.full_like(self.loc, 1 - finfo.eps))
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transforms = [ExpTransform().inv, AffineTransform(loc=0, scale=-torch.ones_like(self.scale)),
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ExpTransform().inv, AffineTransform(loc=loc, scale=-self.scale)]
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super(Gumbel, self).__init__(base_dist, transforms, validate_args=validate_args)
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def expand(self, batch_shape, _instance=None):
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new = self._get_checked_instance(Gumbel, _instance)
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new.loc = self.loc.expand(batch_shape)
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new.scale = self.scale.expand(batch_shape)
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return super(Gumbel, self).expand(batch_shape, _instance=new)
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# Explicitly defining the log probability function for Gumbel due to precision issues
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def log_prob(self, value):
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if self._validate_args:
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self._validate_sample(value)
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y = (self.loc - value) / self.scale
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return (y - y.exp()) - self.scale.log()
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@property
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def mean(self):
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return self.loc + self.scale * euler_constant
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@property
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def mode(self):
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return self.loc
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@property
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def stddev(self):
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return (math.pi / math.sqrt(6)) * self.scale
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@property
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def variance(self):
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return self.stddev.pow(2)
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def entropy(self):
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return self.scale.log() + (1 + euler_constant)
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