# Copyright (c) 2019 PaddlePaddle Authors. All Rights Reserved. # # 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. from __future__ import absolute_import from __future__ import division from __future__ import print_function import math import copy import paddle import paddle.nn as nn import paddle.optimizer as optimizer from paddle.optimizer.lr import CosineAnnealingDecay import paddle.regularizer as regularizer from paddle import cos from ppdet.core.workspace import register, serializable __all__ = ['LearningRate', 'OptimizerBuilder'] from ppdet.utils.logger import setup_logger logger = setup_logger(__name__) @serializable class CosineDecay(object): """ Cosine learning rate decay Args: max_epochs (int): max epochs for the training process. if you commbine cosine decay with warmup, it is recommended that the max_iters is much larger than the warmup iter """ def __init__(self, max_epochs=1000, use_warmup=True): self.max_epochs = max_epochs self.use_warmup = use_warmup def __call__(self, base_lr=None, boundary=None, value=None, step_per_epoch=None): assert base_lr is not None, "either base LR or values should be provided" max_iters = self.max_epochs * int(step_per_epoch) if boundary is not None and value is not None and self.use_warmup: for i in range(int(boundary[-1]), max_iters): boundary.append(i) decayed_lr = base_lr * 0.5 * ( math.cos(i * math.pi / max_iters) + 1) value.append(decayed_lr) return optimizer.lr.PiecewiseDecay(boundary, value) return optimizer.lr.CosineAnnealingDecay(base_lr, T_max=max_iters) @serializable class PiecewiseDecay(object): """ Multi step learning rate decay Args: gamma (float | list): decay factor milestones (list): steps at which to decay learning rate """ def __init__(self, gamma=[0.1, 0.01], milestones=[8, 11], values=None, use_warmup=True): super(PiecewiseDecay, self).__init__() if type(gamma) is not list: self.gamma = [] for i in range(len(milestones)): self.gamma.append(gamma / 10**i) else: self.gamma = gamma self.milestones = milestones self.values = values self.use_warmup = use_warmup def __call__(self, base_lr=None, boundary=None, value=None, step_per_epoch=None): if boundary is not None and self.use_warmup: boundary.extend([int(step_per_epoch) * i for i in self.milestones]) else: # do not use LinearWarmup boundary = [int(step_per_epoch) * i for i in self.milestones] # self.values is setted directly in config if self.values is not None: assert len(self.milestones) + 1 == len(self.values) return optimizer.lr.PiecewiseDecay(boundary, self.values) # value is computed by self.gamma if value is not None: for i in self.gamma: value.append(base_lr * i) return optimizer.lr.PiecewiseDecay(boundary, value) @serializable class LinearWarmup(object): """ Warm up learning rate linearly Args: steps (int): warm up steps start_factor (float): initial learning rate factor """ def __init__(self, steps=500, start_factor=1. / 3): super(LinearWarmup, self).__init__() self.steps = steps self.start_factor = start_factor def __call__(self, base_lr): boundary = [] value = [] for i in range(self.steps + 1): alpha = i / self.steps factor = self.start_factor * (1 - alpha) + alpha lr = base_lr * factor value.append(lr) if i > 0: boundary.append(i) return boundary, value @register class LearningRate(object): """ Learning Rate configuration Args: base_lr (float): base learning rate schedulers (list): learning rate schedulers """ __category__ = 'optim' def __init__(self, base_lr=0.01, schedulers=[PiecewiseDecay(), LinearWarmup()]): super(LearningRate, self).__init__() self.base_lr = base_lr self.schedulers = schedulers def __call__(self, step_per_epoch): assert len(self.schedulers) >= 1 if not self.schedulers[0].use_warmup: return self.schedulers[0](base_lr=self.base_lr, step_per_epoch=step_per_epoch) # TODO: split warmup & decay # warmup boundary, value = self.schedulers[1](self.base_lr) # decay decay_lr = self.schedulers[0](self.base_lr, boundary, value, step_per_epoch) return decay_lr @register class OptimizerBuilder(): """ Build optimizer handles Args: regularizer (object): an `Regularizer` instance optimizer (object): an `Optimizer` instance """ __category__ = 'optim' def __init__(self, clip_grad_by_norm=None, regularizer={'type': 'L2', 'factor': .0001}, optimizer={'type': 'Momentum', 'momentum': .9}): self.clip_grad_by_norm = clip_grad_by_norm self.regularizer = regularizer self.optimizer = optimizer def __call__(self, learning_rate, params=None): if self.clip_grad_by_norm is not None: grad_clip = nn.ClipGradByGlobalNorm( clip_norm=self.clip_grad_by_norm) else: grad_clip = None if self.regularizer: reg_type = self.regularizer['type'] + 'Decay' reg_factor = self.regularizer['factor'] regularization = getattr(regularizer, reg_type)(reg_factor) else: regularization = None optim_args = self.optimizer.copy() optim_type = optim_args['type'] del optim_args['type'] op = getattr(optimizer, optim_type) return op(learning_rate=learning_rate, parameters=params, weight_decay=regularization, grad_clip=grad_clip, **optim_args) class ModelEMA(object): def __init__(self, decay, model, use_thres_step=False): self.step = 0 self.decay = decay self.state_dict = dict() for k, v in model.state_dict().items(): self.state_dict[k] = paddle.zeros_like(v) self.use_thres_step = use_thres_step def update(self, model): if self.use_thres_step: decay = min(self.decay, (1 + self.step) / (10 + self.step)) else: decay = self.decay self._decay = decay model_dict = model.state_dict() for k, v in self.state_dict.items(): v = decay * v + (1 - decay) * model_dict[k] v.stop_gradient = True self.state_dict[k] = v self.step += 1 def apply(self): state_dict = dict() for k, v in self.state_dict.items(): v = v / (1 - self._decay**self.step) v.stop_gradient = True state_dict[k] = v return state_dict