torch/distributions/weibull.py - platform/external/pytorch - Git at Google

 import torch
 from torch.distributions import constraints
 from torch.distributions.exponential import Exponential
 from torch.distributions.transformed_distribution import TransformedDistribution
 from torch.distributions.transforms import AffineTransform, PowerTransform
 from torch.distributions.utils import broadcast_all
 from torch.distributions.gumbel import euler_constant


 class Weibull(TransformedDistribution):
     r"""
     Samples from a two-parameter Weibull distribution.

     Example:

         >>> m = Weibull(torch.tensor([1.0]), torch.tensor([1.0]))
         >>> m.sample()  # sample from a Weibull distribution with scale=1, concentration=1
         tensor([ 0.4784])

     Args:
         scale (float or Tensor): Scale parameter of distribution (lambda).
         concentration (float or Tensor): Concentration parameter of distribution (k/shape).
     """
     arg_constraints = {'scale': constraints.positive, 'concentration': constraints.positive}
     support = constraints.positive

     def __init__(self, scale, concentration, validate_args=None):
         self.scale, self.concentration = broadcast_all(scale, concentration)
         self.concentration_reciprocal = self.concentration.reciprocal()
         base_dist = Exponential(torch.ones_like(self.scale))
         transforms = [PowerTransform(exponent=self.concentration_reciprocal),
                       AffineTransform(loc=0, scale=self.scale)]
         super(Weibull, self).__init__(base_dist,
                                       transforms,
                                       validate_args=validate_args)

     def expand(self, batch_shape, _instance=None):
         new = self._get_checked_instance(Weibull, _instance)
         new.scale = self.scale.expand(batch_shape)
         new.concentration = self.concentration.expand(batch_shape)
         new.concentration_reciprocal = new.concentration.reciprocal()
         base_dist = self.base_dist.expand(batch_shape)
         transforms = [PowerTransform(exponent=new.concentration_reciprocal),
                       AffineTransform(loc=0, scale=new.scale)]
         super(Weibull, new).__init__(base_dist,
                                      transforms,
                                      validate_args=False)
         new._validate_args = self._validate_args
         return new

     @property
     def mean(self):
         return self.scale * torch.exp(torch.lgamma(1 + self.concentration_reciprocal))

     @property
     def variance(self):
         return self.scale.pow(2) * (torch.exp(torch.lgamma(1 + 2 * self.concentration_reciprocal)) -
                                     torch.exp(2 * torch.lgamma(1 + self.concentration_reciprocal)))

     def entropy(self):
         return euler_constant * (1 - self.concentration_reciprocal) + \
             torch.log(self.scale * self.concentration_reciprocal) + 1
	import torch
	from torch.distributions import constraints
	from torch.distributions.exponential import Exponential
	from torch.distributions.transformed_distribution import TransformedDistribution
	from torch.distributions.transforms import AffineTransform, PowerTransform
	from torch.distributions.utils import broadcast_all
	from torch.distributions.gumbel import euler_constant


	class Weibull(TransformedDistribution):
	r"""
	Samples from a two-parameter Weibull distribution.

	Example:

	>>> m = Weibull(torch.tensor([1.0]), torch.tensor([1.0]))
	>>> m.sample() # sample from a Weibull distribution with scale=1, concentration=1
	tensor([ 0.4784])

	Args:
	scale (float or Tensor): Scale parameter of distribution (lambda).
	concentration (float or Tensor): Concentration parameter of distribution (k/shape).
	"""
	arg_constraints = {'scale': constraints.positive, 'concentration': constraints.positive}
	support = constraints.positive

	def __init__(self, scale, concentration, validate_args=None):
	self.scale, self.concentration = broadcast_all(scale, concentration)
	self.concentration_reciprocal = self.concentration.reciprocal()
	base_dist = Exponential(torch.ones_like(self.scale))
	transforms = [PowerTransform(exponent=self.concentration_reciprocal),
	AffineTransform(loc=0, scale=self.scale)]
	super(Weibull, self).__init__(base_dist,
	transforms,
	validate_args=validate_args)

	def expand(self, batch_shape, _instance=None):
	new = self._get_checked_instance(Weibull, _instance)
	new.scale = self.scale.expand(batch_shape)
	new.concentration = self.concentration.expand(batch_shape)
	new.concentration_reciprocal = new.concentration.reciprocal()
	base_dist = self.base_dist.expand(batch_shape)
	transforms = [PowerTransform(exponent=new.concentration_reciprocal),
	AffineTransform(loc=0, scale=new.scale)]
	super(Weibull, new).__init__(base_dist,
	transforms,
	validate_args=False)
	new._validate_args = self._validate_args
	return new

	@property
	def mean(self):
	return self.scale * torch.exp(torch.lgamma(1 + self.concentration_reciprocal))

	@property
	def variance(self):
	return self.scale.pow(2) * (torch.exp(torch.lgamma(1 + 2 * self.concentration_reciprocal)) -
	torch.exp(2 * torch.lgamma(1 + self.concentration_reciprocal)))

	def entropy(self):
	return euler_constant * (1 - self.concentration_reciprocal) + \
	torch.log(self.scale * self.concentration_reciprocal) + 1