torch/distributed/optim/functional_adadelta.py - platform/external/pytorch - Git at Google

 from typing import List, Dict, Optional
 import torch
 import torch.optim._functional as F

 from torch import Tensor

 # Define a TorchScript compatible Functional Adadelta Optimizer
 # where we use these optimizer in a functional way.
 # Instead of using the `param.grad` when updating parameters,
 # we explicitly allow the distributed optimizer pass gradients to
 # the `step` function. In this way, we could separate the gradients
 # and parameters and allow multithreaded trainer to update the
 # parameters without data traces on accumulating to the same .grad.
 # NOTE: This should be only used by distributed optimizer internals
 # and not meant to expose to the user.
 @torch.jit.script
 class _FunctionalAdadelta(object):
     def __init__(
         self,
         params: List[Tensor],
         lr: float = 1.0,
         rho: float = 0.9,
         eps: float = 1e-6,
         weight_decay: float = 0.0,
         _allow_empty_param_list: bool = False,
     ):
         self.defaults = {
             "lr": lr,
             "rho": rho,
             "eps": eps,
             "weight_decay": weight_decay,
         }

         if len(params) == 0 and not _allow_empty_param_list:
             raise ValueError("optimizer got an empty parameter list")

         # NOTE: we only have one param_group and don't allow user to add additional
         # param group as it's not a common use case.
         self.param_group = {"params": params}

         self.state = torch.jit.annotate(Dict[torch.Tensor, Dict[str, torch.Tensor]], {})

     def step(self, gradients: List[Optional[Tensor]]):
         params = self.param_group['params']
         params_with_grad = []
         grads = []
         square_avgs = []
         acc_deltas = []
         lr = self.defaults['lr']
         rho = self.defaults['rho']
         eps = self.defaults['eps']
         weight_decay = self.defaults['weight_decay']

         if len(params) != len(gradients):
             raise ValueError(
                 "the gradients passed in does not equal to the size of the parameters!"
                 + f"Params length: {len(params)}. "
                 + f"Gradients length: {len(gradients)}"
             )

         for param, gradient in zip(params, gradients):
             if gradient is not None:
                 params_with_grad.append(param)
                 grads.append(gradient)
                 # Lazy state initialization
                 if param not in self.state:
                     self.state[param] = {}
                     state = self.state[param]
                     state['step'] = torch.tensor(0.0)
                     state['square_avg'] = torch.zeros_like(param, memory_format=torch.preserve_format)
                     state['acc_delta'] = torch.zeros_like(param, memory_format=torch.preserve_format)

                 state = self.state[param]
                 square_avgs.append(state['square_avg'])
                 acc_deltas.append(state['acc_delta'])

         with torch.no_grad():
             F.adadelta(params_with_grad,
                        grads,
                        square_avgs,
                        acc_deltas,
                        lr=lr,
                        rho=rho,
                        eps=eps,
                        weight_decay=weight_decay)
	from typing import List, Dict, Optional
	import torch
	import torch.optim._functional as F

	from torch import Tensor

	# Define a TorchScript compatible Functional Adadelta Optimizer
	# where we use these optimizer in a functional way.
	# Instead of using the `param.grad` when updating parameters,
	# we explicitly allow the distributed optimizer pass gradients to
	# the `step` function. In this way, we could separate the gradients
	# and parameters and allow multithreaded trainer to update the
	# parameters without data traces on accumulating to the same .grad.
	# NOTE: This should be only used by distributed optimizer internals
	# and not meant to expose to the user.
	@torch.jit.script
	class _FunctionalAdadelta(object):
	def __init__(
	self,
	params: List[Tensor],
	lr: float = 1.0,
	rho: float = 0.9,
	eps: float = 1e-6,
	weight_decay: float = 0.0,
	_allow_empty_param_list: bool = False,
	):
	self.defaults = {
	"lr": lr,
	"rho": rho,
	"eps": eps,
	"weight_decay": weight_decay,
	}

	if len(params) == 0 and not _allow_empty_param_list:
	raise ValueError("optimizer got an empty parameter list")

	# NOTE: we only have one param_group and don't allow user to add additional
	# param group as it's not a common use case.
	self.param_group = {"params": params}

	self.state = torch.jit.annotate(Dict[torch.Tensor, Dict[str, torch.Tensor]], {})

	def step(self, gradients: List[Optional[Tensor]]):
	params = self.param_group['params']
	params_with_grad = []
	grads = []
	square_avgs = []
	acc_deltas = []
	lr = self.defaults['lr']
	rho = self.defaults['rho']
	eps = self.defaults['eps']
	weight_decay = self.defaults['weight_decay']

	if len(params) != len(gradients):
	raise ValueError(
	"the gradients passed in does not equal to the size of the parameters!"
	+ f"Params length: {len(params)}. "
	+ f"Gradients length: {len(gradients)}"
	)

	for param, gradient in zip(params, gradients):
	if gradient is not None:
	params_with_grad.append(param)
	grads.append(gradient)
	# Lazy state initialization
	if param not in self.state:
	self.state[param] = {}
	state = self.state[param]
	state['step'] = torch.tensor(0.0)
	state['square_avg'] = torch.zeros_like(param, memory_format=torch.preserve_format)
	state['acc_delta'] = torch.zeros_like(param, memory_format=torch.preserve_format)

	state = self.state[param]
	square_avgs.append(state['square_avg'])
	acc_deltas.append(state['acc_delta'])

	with torch.no_grad():
	F.adadelta(params_with_grad,
	grads,
	square_avgs,
	acc_deltas,
	lr=lr,
	rho=rho,
	eps=eps,
	weight_decay=weight_decay)