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scheduler.py
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scheduler.py
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from math import cos, pi, floor, sin
from torch.optim import lr_scheduler
class CosineLR(lr_scheduler._LRScheduler):
def __init__(self, optimizer, lr_min, lr_max, step_size):
self.lr_min = lr_min
self.lr_max = lr_max
self.step_size = step_size
self.iteration = 0
super().__init__(optimizer, -1)
def get_lr(self):
lr = self.lr_min + 0.5 * (self.lr_max - self.lr_min) * (
1 + cos(self.iteration / self.step_size * pi)
)
self.iteration += 1
if self.iteration == self.step_size:
self.iteration = 0
return [lr for base_lr in self.base_lrs]
class PowerLR(lr_scheduler._LRScheduler):
def __init__(self, optimizer, lr_min, lr_max, warmup):
self.lr_min = lr_min
self.lr_max = lr_max
self.warmup = warmup
self.iteration = 0
super().__init__(optimizer, -1)
def get_lr(self):
if self.iteration < self.warmup:
lr = (
self.lr_min + (self.lr_max - self.lr_min) / self.warmup * self.iteration
)
else:
lr = self.lr_max * (self.iteration - self.warmup + 1) ** -0.5
self.iteration += 1
return [lr for base_lr in self.base_lrs]
class SineLR(lr_scheduler._LRScheduler):
def __init__(self, optimizer, lr_min, lr_max, step_size):
self.lr_min = lr_min
self.lr_max = lr_max
self.step_size = step_size
self.iteration = 0
super().__init__(optimizer, -1)
def get_lr(self):
lr = self.lr_min + (self.lr_max - self.lr_min) * sin(
self.iteration / self.step_size * pi
)
self.iteration += 1
if self.iteration == self.step_size:
self.iteration = 0
return [lr for base_lr in self.base_lrs]
class LinearLR(lr_scheduler._LRScheduler):
def __init__(self, optimizer, lr_min, lr_max, warmup, step_size):
self.lr_min = lr_min
self.lr_max = lr_max
self.step_size = step_size
self.warmup = warmup
self.iteration = 0
super().__init__(optimizer, -1)
def get_lr(self):
if self.iteration < self.warmup:
lr = self.lr_max
else:
lr = self.lr_max + (self.iteration - self.warmup) * (
self.lr_min - self.lr_max
) / (self.step_size - self.warmup)
self.iteration += 1
if self.iteration == self.step_size:
self.iteration = 0
return [lr for base_lr in self.base_lrs]
class CLR(lr_scheduler._LRScheduler):
def __init__(self, optimizer, lr_min, lr_max, step_size):
self.epoch = 0
self.lr_min = lr_min
self.lr_max = lr_max
self.current_lr = lr_min
self.step_size = step_size
super().__init__(optimizer, -1)
def get_lr(self):
cycle = floor(1 + self.epoch / (2 * self.step_size))
x = abs(self.epoch / self.step_size - 2 * cycle + 1)
lr = self.lr_min + (self.lr_max - self.lr_min) * max(0, 1 - x)
self.current_lr = lr
self.epoch += 1
return [lr for base_lr in self.base_lrs]
class Warmup(lr_scheduler._LRScheduler):
def __init__(self, optimizer, model_dim, factor=1, warmup=16000):
self.optimizer = optimizer
self.model_dim = model_dim
self.factor = factor
self.warmup = warmup
self.iteration = 0
super().__init__(optimizer, -1)
def get_lr(self):
self.iteration += 1
lr = (
self.factor
* self.model_dim ** (-0.5)
* min(self.iteration ** (-0.5), self.iteration * self.warmup ** (-1.5))
)
return [lr for base_lr in self.base_lrs]
# Copyright 2019 fastai
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
# http://www.apache.org/licenses/LICENSE-2.0
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# Borrowed from https://github.com/fastai/fastai and changed to make it runs like PyTorch lr scheduler
class CycleAnnealScheduler:
def __init__(
self, optimizer, lr_max, lr_divider, cut_point, step_size, momentum=None
):
self.lr_max = lr_max
self.lr_divider = lr_divider
self.cut_point = step_size // cut_point
self.step_size = step_size
self.iteration = 0
self.cycle_step = int(step_size * (1 - cut_point / 100) / 2)
self.momentum = momentum
self.optimizer = optimizer
def get_lr(self):
if self.iteration > 2 * self.cycle_step:
cut = (self.iteration - 2 * self.cycle_step) / (
self.step_size - 2 * self.cycle_step
)
lr = self.lr_max * (1 + (cut * (1 - 100) / 100)) / self.lr_divider
elif self.iteration > self.cycle_step:
cut = 1 - (self.iteration - self.cycle_step) / self.cycle_step
lr = self.lr_max * (1 + cut * (self.lr_divider - 1)) / self.lr_divider
else:
cut = self.iteration / self.cycle_step
lr = self.lr_max * (1 + cut * (self.lr_divider - 1)) / self.lr_divider
return lr
def get_momentum(self):
if self.iteration > 2 * self.cycle_step:
momentum = self.momentum[0]
elif self.iteration > self.cycle_step:
cut = 1 - (self.iteration - self.cycle_step) / self.cycle_step
momentum = self.momentum[0] + cut * (self.momentum[1] - self.momentum[0])
else:
cut = self.iteration / self.cycle_step
momentum = self.momentum[0] + cut * (self.momentum[1] - self.momentum[0])
return momentum
def step(self):
lr = self.get_lr()
if self.momentum is not None:
momentum = self.get_momentum()
self.iteration += 1
if self.iteration == self.step_size:
self.iteration = 0
for group in self.optimizer.param_groups:
group['lr'] = lr
if self.momentum is not None:
group['betas'] = (momentum, group['betas'][1])
return lr
def anneal_linear(start, end, proportion):
return start + proportion * (end - start)
def anneal_cos(start, end, proportion):
cos_val = cos(pi * proportion) + 1
return end + (start - end) / 2 * cos_val
class Phase:
def __init__(self, start, end, n_iter, anneal_fn):
self.start, self.end = start, end
self.n_iter = n_iter
self.anneal_fn = anneal_fn
self.n = 0
def step(self):
self.n += 1
return self.anneal_fn(self.start, self.end, self.n / self.n_iter)
def reset(self):
self.n = 0
@property
def is_done(self):
return self.n >= self.n_iter
class CycleScheduler:
def __init__(
self,
optimizer,
lr_max,
n_iter,
momentum=(0.95, 0.85),
divider=25,
warmup_proportion=0.3,
phase=('linear', 'cos'),
):
self.optimizer = optimizer
phase1 = int(n_iter * warmup_proportion)
phase2 = n_iter - phase1
lr_min = lr_max / divider
phase_map = {'linear': anneal_linear, 'cos': anneal_cos}
self.lr_phase = [
Phase(lr_min, lr_max, phase1, phase_map[phase[0]]),
Phase(lr_max, lr_min / 1e4, phase2, phase_map[phase[1]]),
]
self.momentum = momentum
if momentum is not None:
mom1, mom2 = momentum
self.momentum_phase = [
Phase(mom1, mom2, phase1, phase_map[phase[0]]),
Phase(mom2, mom1, phase2, phase_map[phase[1]]),
]
else:
self.momentum_phase = []
self.phase = 0
def step(self):
lr = self.lr_phase[self.phase].step()
if self.momentum is not None:
momentum = self.momentum_phase[self.phase].step()
else:
momentum = None
for group in self.optimizer.param_groups:
group['lr'] = lr
if self.momentum is not None:
if 'betas' in group:
group['betas'] = (momentum, group['betas'][1])
else:
group['momentum'] = momentum
if self.lr_phase[self.phase].is_done:
self.phase += 1
if self.phase >= len(self.lr_phase):
for phase in self.lr_phase:
phase.reset()
for phase in self.momentum_phase:
phase.reset()
self.phase = 0
return lr, momentum
class LRFinder(lr_scheduler._LRScheduler):
def __init__(self, optimizer, lr_min, lr_max, step_size, linear=False):
ratio = lr_max / lr_min
self.linear = linear
self.lr_min = lr_min
self.lr_mult = (ratio / step_size) if linear else ratio ** (1 / step_size)
self.iteration = 0
self.lrs = []
self.losses = []
super().__init__(optimizer, -1)
def get_lr(self):
lr = (
self.lr_mult * self.iteration
if self.linear
else self.lr_mult ** self.iteration
)
lr = self.lr_min + lr if self.linear else self.lr_min * lr
self.iteration += 1
self.lrs.append(lr)
return [lr for base_lr in self.base_lrs]
def record(self, loss):
self.losses.append(loss)
def save(self, filename):
with open(filename, 'w') as f:
for lr, loss in zip(self.lrs, self.losses):
f.write('{},{}\n'.format(lr, loss))