2020-01-13 19:55:45 +01:00
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import torch
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import torch.nn.utils.rnn as rnn
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from enum import Enum
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import functools
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import numpy as np
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import math
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class ModeKeys(Enum):
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TRAIN = 1
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EVAL = 2
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PREDICT = 3
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2020-04-06 03:43:49 +02:00
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def cyclical_lr(stepsize, min_lr=3e-4, max_lr=3e-3, decay=1.):
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2020-01-13 19:55:45 +01:00
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# Lambda function to calculate the LR
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lr_lambda = lambda it: min_lr + (max_lr - min_lr) * relative(it, stepsize) * decay**it
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# Additional function to see where on the cycle we are
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def relative(it, stepsize):
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cycle = math.floor(1 + it / (2 * stepsize))
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x = abs(it / stepsize - 2 * cycle + 1)
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return max(0, (1 - x))
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return lr_lambda
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2020-04-06 03:43:49 +02:00
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def to_one_hot(labels, n_labels):
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return torch.eye(n_labels, device=labels.device)[labels]
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2020-01-13 19:55:45 +01:00
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def exp_anneal(anneal_kws):
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device = anneal_kws['device']
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start = torch.tensor(anneal_kws['start'], device=device)
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finish = torch.tensor(anneal_kws['finish'], device=device)
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rate = torch.tensor(anneal_kws['rate'], device=device)
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return lambda step: finish - (finish - start)*torch.pow(rate, torch.tensor(step, dtype=torch.float, device=device))
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def sigmoid_anneal(anneal_kws):
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device = anneal_kws['device']
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start = torch.tensor(anneal_kws['start'], device=device)
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finish = torch.tensor(anneal_kws['finish'], device=device)
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center_step = torch.tensor(anneal_kws['center_step'], device=device, dtype=torch.float)
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steps_lo_to_hi = torch.tensor(anneal_kws['steps_lo_to_hi'], device=device, dtype=torch.float)
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return lambda step: start + (finish - start)*torch.sigmoid((torch.tensor(float(step), device=device) - center_step) * (1./steps_lo_to_hi))
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class CustomLR(torch.optim.lr_scheduler.LambdaLR):
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def __init__(self, optimizer, lr_lambda, last_epoch=-1):
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super(CustomLR, self).__init__(optimizer, lr_lambda, last_epoch)
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def get_lr(self):
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return [lmbda(self.last_epoch)
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for lmbda, base_lr in zip(self.lr_lambdas, self.base_lrs)]
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2020-04-06 03:43:49 +02:00
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def mutual_inf_mc(x_dist):
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dist = x_dist.__class__
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H_y = dist(probs=x_dist.probs.mean(dim=0)).entropy()
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return (H_y - x_dist.entropy().mean(dim=0)).sum()
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def run_lstm_on_variable_length_seqs(lstm_module, original_seqs, lower_indices=None, upper_indices=None, total_length=None):
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bs, tf = original_seqs.shape[:2]
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if lower_indices is None:
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lower_indices = torch.zeros(bs, dtype=torch.int)
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if upper_indices is None:
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upper_indices = torch.ones(bs, dtype=torch.int) * (tf - 1)
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if total_length is None:
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total_length = max(upper_indices) + 1
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2020-01-13 19:55:45 +01:00
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# This is done so that we can just pass in self.prediction_timesteps
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# (which we want to INCLUDE, so this will exclude the next timestep).
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2020-04-06 03:43:49 +02:00
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inclusive_break_indices = upper_indices + 1
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2020-01-13 19:55:45 +01:00
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pad_list = list()
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for i, seq_len in enumerate(inclusive_break_indices):
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pad_list.append(original_seqs[i, lower_indices[i]:seq_len])
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packed_seqs = rnn.pack_sequence(pad_list, enforce_sorted=False)
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packed_output, (h_n, c_n) = lstm_module(packed_seqs)
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output, _ = rnn.pad_packed_sequence(packed_output,
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batch_first=True,
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total_length=total_length)
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return output, (h_n, c_n)
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def extract_subtensor_per_batch_element(tensor, indices):
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batch_idxs = torch.arange(start=0, end=len(indices))
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batch_idxs = batch_idxs[~torch.isnan(indices)]
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indices = indices[~torch.isnan(indices)]
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if indices.size == 0:
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return None
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else:
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indices = indices.long()
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if tensor.is_cuda:
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batch_idxs = batch_idxs.to(tensor.get_device())
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indices = indices.to(tensor.get_device())
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return tensor[batch_idxs, indices]
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def unpack_RNN_state(state_tuple):
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# PyTorch returned LSTM states have 3 dims:
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# (num_layers * num_directions, batch, hidden_size)
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state = torch.cat(state_tuple, dim=0).permute(1, 0, 2)
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# Now state is (batch, 2 * num_layers * num_directions, hidden_size)
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state_size = state.size()
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return torch.reshape(state, (-1, state_size[1] * state_size[2]))
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def rsetattr(obj, attr, val):
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pre, _, post = attr.rpartition('.')
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return setattr(rgetattr(obj, pre) if pre else obj, post, val)
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# using wonder's beautiful simplification:
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# https://stackoverflow.com/questions/31174295/getattr-and-setattr-on-nested-objects/31174427?noredirect=1#comment86638618_31174427
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def rgetattr(obj, attr, *args):
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def _getattr(obj, attr):
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return getattr(obj, attr, *args)
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return functools.reduce(_getattr, [obj] + attr.split('.'))
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