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Running
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Zero
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import os
import torch
from collections import OrderedDict
from abc import ABC, abstractmethod
from . import networks
import numpy as np
from torch.nn.parallel import DistributedDataParallel as DDP
class BaseModel(ABC):
"""This class is an abstract base class (ABC) for models.
To create a subclass, you need to implement the following five functions:
-- <__init__>: initialize the class; first call BaseModel.__init__(self, opt).
-- <set_input>: unpack data from dataset and apply preprocessing.
-- <forward>: produce intermediate results.
-- <optimize_parameters>: calculate losses, gradients, and update network weights.
-- <modify_commandline_options>: (optionally) add model-specific options and set default options.
"""
def __init__(self, opt):
"""Initialize the BaseModel class.
Parameters:
opt (Option class)-- stores all the experiment flags; needs to be a subclass of BaseOptions
When creating your custom class, you need to implement your own initialization.
In this fucntion, you should first call `BaseModel.__init__(self, opt)`
Then, you need to define four lists:
-- self.loss_names (str list): specify the training losses that you want to plot and save.
-- self.model_names (str list): specify the images that you want to display and save.
-- self.visual_names (str list): define networks used in our training.
-- self.optimizers (optimizer list): define and initialize optimizers. You can define one optimizer for each network. If two networks are updated at the same time, you can use itertools.chain to group them. See cycle_gan_model.py for an example.
"""
self.opt = opt
self.gpu_ids = opt.gpu_ids
self.isTrain = opt.isTrain
self.iter = 0
self.last_iter = 0
self.device = torch.device('cuda:{}'.format(
self.gpu_ids[0])) if self.gpu_ids else torch.device('cpu') # get device name: CPU or GPU
# save all the checkpoints to save_dir
self.save_dir = os.path.join(opt.checkpoints_dir, opt.name)
try:
os.mkdir(self.save_dir)
except:
pass
# with [scale_width], input images might have different sizes, which hurts the performance of cudnn.benchmark.
if opt.preprocess != 'scale_width':
torch.backends.cudnn.benchmark = True
self.loss_names = []
self.model_names = []
self.visual_names = []
self.optimizers = []
self.image_paths = []
self.label_colours = np.random.randint(255, size=(100,3))
def save_suppixel(self,l_inds):
im_target_rgb = np.array([self.label_colours[ c % 100 ] for c in l_inds])
b,h,w = l_inds.shape
im_target_rgb = im_target_rgb.reshape(b,h,w,3).transpose(0,3,1,2)/127.5-1.0
return torch.from_numpy(im_target_rgb)
@staticmethod
def modify_commandline_options(parser, is_train):
"""Add new model-specific options, and rewrite default values for existing options.
Parameters:
parser -- original option parser
is_train (bool) -- whether training phase or test phase. You can use this flag to add training-specific or test-specific options.
Returns:
the modified parser.
"""
return parser
@abstractmethod
def set_input(self, input):
"""Unpack input data from the dataloader and perform necessary pre-processing steps.
Parameters:
input (dict): includes the data itself and its metadata information.
"""
pass
@abstractmethod
def forward(self):
"""Run forward pass; called by both functions <optimize_parameters> and <test>."""
pass
def is_train(self):
"""check if the current batch is good for training."""
return True
@abstractmethod
def optimize_parameters(self):
"""Calculate losses, gradients, and update network weights; called in every training iteration"""
pass
def setup(self, opt):
"""Load and print networks; create schedulers
Parameters:
opt (Option class) -- stores all the experiment flags; needs to be a subclass of BaseOptions
"""
if self.isTrain:
self.schedulers = [networks.get_scheduler(
optimizer, opt) for optimizer in self.optimizers]
if not self.isTrain or opt.continue_train:
self.load_networks(opt.epoch)
self.print_networks(opt.verbose)
def eval(self):
"""Make models eval mode during test time"""
for name in self.model_names:
if isinstance(name, str):
net = getattr(self, 'net' + name)
net.eval()
def test(self):
"""Forward function used in test time.
This function wraps <forward> function in no_grad() so we don't save intermediate steps for backprop
It also calls <compute_visuals> to produce additional visualization results
"""
with torch.no_grad():
self.forward()
self.compute_visuals()
def compute_visuals(self):
"""Calculate additional output images for visdom and HTML visualization"""
pass
def get_image_paths(self):
""" Return image paths that are used to load current data"""
return self.image_paths
def update_learning_rate(self):
"""Update learning rates for all the networks; called at the end of every epoch"""
for scheduler in self.schedulers:
scheduler.step()
lr = self.optimizers[0].param_groups[0]['lr']
print('learning rate = %.7f' % lr)
def get_current_visuals(self):
"""Return visualization images. train.py will display these images with visdom, and save the images to a HTML"""
visual_ret = OrderedDict()
for name in self.visual_names:
if isinstance(name, str):
if 'Lab' in name:
labimg = getattr(self, name).cpu()
labimg[:,0,:,:]+=1
labimg[:,0,:,:]*=50
labimg[:,1:,:,:] *= 110
labimg = labimg.permute((0,2,3,1))
for i in range(labimg.shape[0]):
labimg[i,:,:,:]=lab2rgb(labimg[i,:,:,:])
visual_ret[name] = (labimg.permute((0,3,1,2))*2-1.0).to(self.device)
elif 'Fm' in name:
visual_ret[name] = self.save_suppixel(getattr(self, name).cpu()).to(self.device)
else:
visual_ret[name] = getattr(self, name)
return visual_ret
def get_current_losses(self):
"""Return traning losses / errors. train.py will print out these errors on console, and save them to a file"""
errors_ret = OrderedDict()
for name in self.loss_names:
if isinstance(name, str):
# float(...) works for both scalar tensor and float number
errors_ret[name] = float(getattr(self, 'loss_' + name))
return errors_ret
def save_networks(self, epoch):
"""Save all the networks to the disk.
Parameters:
epoch (int) -- current epoch; used in the file name '%s_net_%s.pth' % (epoch, name)
"""
for name in self.model_names:
if isinstance(name, str):
save_filename = '%s_net_%s.pth' % (epoch, name)
save_path = os.path.join(self.save_dir, save_filename)
# print(save_path)
net = getattr(self, 'net' + name)
if len(self.gpu_ids) > 0 and torch.cuda.is_available():
torch.save(net.state_dict(), save_path)
# net.cuda(self.gpu_ids[0])
else:
torch.save(net.cpu().state_dict(), save_path)
save_filename = '%s_net_opt.pth' % (epoch)
save_path = os.path.join(self.save_dir, save_filename)
save_dict = {'iter': str(self.iter // self.opt.print_freq * self.opt.print_freq)}
for i, name in enumerate(self.optimizer_names):
save_dict.update({name.lower(): self.optimizers[i].state_dict()})
torch.save(save_dict, save_path)
def __patch_instance_norm_state_dict(self, state_dict, module, keys, i=0):
"""Fix InstanceNorm checkpoints incompatibility (prior to 0.4)"""
key = keys[i]
if i + 1 == len(keys): # at the end, pointing to a parameter/buffer
if module.__class__.__name__.startswith('InstanceNorm') and \
(key == 'running_mean' or key == 'running_var'):
if getattr(module, key) is None:
state_dict.pop('.'.join(keys))
if module.__class__.__name__.startswith('InstanceNorm') and \
(key == 'num_batches_tracked'):
state_dict.pop('.'.join(keys))
else:
self.__patch_instance_norm_state_dict(
state_dict, getattr(module, key), keys, i + 1)
def load_networks(self, epoch):
"""Load all the networks from the disk.
Parameters:
epoch (int) -- current epoch; used in the file name '%s_net_%s.pth' % (epoch, name)
"""
for name in self.model_names:
if isinstance(name, str):
load_filename = '%s_net_%s.pth' % (epoch, name)
load_path = os.path.join(self.save_dir, load_filename)
net = getattr(self, 'net' + name)
# if isinstance(net, torch.nn.DataParallel):
if isinstance(net, DDP):
net = net.module
# print(net)
print('loading the model from %s' % load_path)
# if you are using PyTorch newer than 0.4 (e.g., built from
# GitHub source), you can remove str() on self.device
state_dict = torch.load(
load_path, map_location=lambda storage, loc: storage.cuda())
if hasattr(state_dict, '_metadata'):
del state_dict._metadata
# patch InstanceNorm checkpoints prior to 0.4
# need to copy keys here because we mutate in loop
#for key in list(state_dict.keys()):
# self.__patch_instance_norm_state_dict(
# state_dict, net, key.split('.'))
net.load_state_dict(state_dict)
del state_dict
def print_networks(self, verbose):
"""Print the total number of parameters in the network and (if verbose) network architecture
Parameters:
verbose (bool) -- if verbose: print the network architecture
"""
print('---------- Networks initialized -------------')
for name in self.model_names:
if isinstance(name, str):
net = getattr(self, 'net' + name)
num_params = 0
for param in net.parameters():
num_params += param.numel()
if verbose:
print(net)
print('[Network %s] Total number of parameters : %.3f M' %
(name, num_params / 1e6))
print('-----------------------------------------------')
def set_requires_grad(self, nets, requires_grad=False):
"""Set requires_grad=False for all the networks to avoid unnecessary computations
Parameters:
nets (network list) -- a list of networks
requires_grad (bool) -- whether the networks require gradients or not
"""
if not isinstance(nets, list):
nets = [nets]
for net in nets:
if net is not None:
for param in net.parameters():
param.requires_grad = requires_grad
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