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Source code for mmpose.core.fp16.hooks

# Copyright (c) OpenMMLab. All rights reserved.
import copy

import torch
import torch.nn as nn
from mmcv.runner import OptimizerHook
from mmcv.utils import _BatchNorm

from ..utils.dist_utils import allreduce_grads
from .utils import cast_tensor_type


[docs]class Fp16OptimizerHook(OptimizerHook): """FP16 optimizer hook. The steps of fp16 optimizer is as follows. 1. Scale the loss value. 2. BP in the fp16 model. 2. Copy gradients from fp16 model to fp32 weights. 3. Update fp32 weights. 4. Copy updated parameters from fp32 weights to fp16 model. Refer to https://arxiv.org/abs/1710.03740 for more details. Args: loss_scale (float): Scale factor multiplied with loss. """ def __init__(self, grad_clip=None, coalesce=True, bucket_size_mb=-1, loss_scale=512., distributed=True): self.grad_clip = grad_clip self.coalesce = coalesce self.bucket_size_mb = bucket_size_mb self.loss_scale = loss_scale self.distributed = distributed
[docs] def before_run(self, runner): """Preparing steps before Mixed Precision Training. 1. Make a master copy of fp32 weights for optimization. 2. Convert the main model from fp32 to fp16. Args: runner (:obj:`mmcv.Runner`): The underlines training runner. """ # keep a copy of fp32 weights runner.optimizer.param_groups = copy.deepcopy( runner.optimizer.param_groups) # convert model to fp16 wrap_fp16_model(runner.model)
[docs] @staticmethod def copy_grads_to_fp32(fp16_net, fp32_weights): """Copy gradients from fp16 model to fp32 weight copy.""" for fp32_param, fp16_param in zip(fp32_weights, fp16_net.parameters()): if fp16_param.grad is not None: if fp32_param.grad is None: fp32_param.grad = fp32_param.data.new(fp32_param.size()) fp32_param.grad.copy_(fp16_param.grad)
[docs] @staticmethod def copy_params_to_fp16(fp16_net, fp32_weights): """Copy updated params from fp32 weight copy to fp16 model.""" for fp16_param, fp32_param in zip(fp16_net.parameters(), fp32_weights): fp16_param.data.copy_(fp32_param.data)
[docs] def after_train_iter(self, runner): """Backward optimization steps for Mixed Precision Training. 1. Scale the loss by a scale factor. 2. Backward the loss to obtain the gradients (fp16). 3. Copy gradients from the model to the fp32 weight copy. 4. Scale the gradients back and update the fp32 weight copy. 5. Copy back the params from fp32 weight copy to the fp16 model. Args: runner (:obj:`mmcv.Runner`): The underlines training runner. """ # clear grads of last iteration runner.model.zero_grad() runner.optimizer.zero_grad() # scale the loss value scaled_loss = runner.outputs['loss'] * self.loss_scale scaled_loss.backward() # copy fp16 grads in the model to fp32 params in the optimizer fp32_weights = [] for param_group in runner.optimizer.param_groups: fp32_weights += param_group['params'] self.copy_grads_to_fp32(runner.model, fp32_weights) # allreduce grads if self.distributed: allreduce_grads(fp32_weights, self.coalesce, self.bucket_size_mb) # scale the gradients back for param in fp32_weights: if param.grad is not None: param.grad.div_(self.loss_scale) if self.grad_clip is not None: self.clip_grads(fp32_weights) # update fp32 params runner.optimizer.step() # copy fp32 params to the fp16 model self.copy_params_to_fp16(runner.model, fp32_weights)
[docs]def wrap_fp16_model(model): """Wrap the FP32 model to FP16. 1. Convert FP32 model to FP16. 2. Remain some necessary layers to be FP32, e.g., normalization layers. Args: model (nn.Module): Model in FP32. """ # convert model to fp16 model.half() # patch the normalization layers to make it work in fp32 mode patch_norm_fp32(model) # set `fp16_enabled` flag for m in model.modules(): if hasattr(m, 'fp16_enabled'): m.fp16_enabled = True
def patch_norm_fp32(module): """Recursively convert normalization layers from FP16 to FP32. Args: module (nn.Module): The modules to be converted in FP16. Returns: nn.Module: The converted module, the normalization layers have been converted to FP32. """ if isinstance(module, (_BatchNorm, nn.GroupNorm)): module.float() module.forward = patch_forward_method(module.forward, torch.half, torch.float) for child in module.children(): patch_norm_fp32(child) return module def patch_forward_method(func, src_type, dst_type, convert_output=True): """Patch the forward method of a module. Args: func (callable): The original forward method. src_type (torch.dtype): Type of input arguments to be converted from. dst_type (torch.dtype): Type of input arguments to be converted to. convert_output (bool): Whether to convert the output back to src_type. Returns: callable: The patched forward method. """ def new_forward(*args, **kwargs): output = func(*cast_tensor_type(args, src_type, dst_type), **cast_tensor_type(kwargs, src_type, dst_type)) if convert_output: output = cast_tensor_type(output, dst_type, src_type) return output return new_forward
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