| import torch |
| import torch.nn as nn |
| from torch.nn import init |
| import functools |
| from torch.optim import lr_scheduler |
| from .util.util import to_device, load_network |
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| def init_weights(net, init_type='normal', init_gain=0.02): |
| """Initialize network weights. |
| |
| Parameters: |
| net (network) -- network to be initialized |
| init_type (str) -- the name of an initialization method: normal | xavier | kaiming | orthogonal |
| init_gain (float) -- scaling factor for normal, xavier and orthogonal. |
| |
| We use 'normal' in the original pix2pix and CycleGAN paper. But xavier and kaiming might |
| work better for some applications. Feel free to try yourself. |
| """ |
| def init_func(m): |
| classname = m.__class__.__name__ |
| if (isinstance(m, nn.Conv2d) |
| or isinstance(m, nn.Linear) |
| or isinstance(m, nn.Embedding)): |
| |
| if init_type == 'N02': |
| init.normal_(m.weight.data, 0.0, init_gain) |
| elif init_type in ['glorot', 'xavier']: |
| init.xavier_normal_(m.weight.data, gain=init_gain) |
| elif init_type == 'kaiming': |
| init.kaiming_normal_(m.weight.data, a=0, mode='fan_in') |
| elif init_type == 'ortho': |
| init.orthogonal_(m.weight.data, gain=init_gain) |
| else: |
| raise NotImplementedError('initialization method [%s] is not implemented' % init_type) |
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| |
| if init_type in ['N02', 'glorot', 'xavier', 'kaiming', 'ortho']: |
| |
| net.apply(init_func) |
| else: |
| |
| net = load_network(net, init_type, 'latest') |
| return net |
|
|
| def init_net(net, init_type='normal', init_gain=0.02, gpu_ids=[]): |
| """Initialize a network: 1. register CPU/GPU device (with multi-GPU support); 2. initialize the network weights |
| Parameters: |
| net (network) -- the network to be initialized |
| init_type (str) -- the name of an initialization method: normal | xavier | kaiming | orthogonal |
| gain (float) -- scaling factor for normal, xavier and orthogonal. |
| gpu_ids (int list) -- which GPUs the network runs on: e.g., 0,1,2 |
| |
| Return an initialized network. |
| """ |
| if len(gpu_ids) > 0: |
| assert(torch.cuda.is_available()) |
| net.to(gpu_ids[0]) |
| net = torch.nn.DataParallel(net, gpu_ids) |
| init_weights(net, init_type, init_gain=init_gain) |
| return net |
|
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|
| def get_scheduler(optimizer, opt): |
| """Return a learning rate scheduler |
| |
| Parameters: |
| optimizer -- the optimizer of the network |
| opt (option class) -- stores all the experiment flags; needs to be a subclass of BaseOptions. |
| opt.lr_policy is the name of learning rate policy: linear | step | plateau | cosine |
| |
| For 'linear', we keep the same learning rate for the first <opt.niter> epochs |
| and linearly decay the rate to zero over the next <opt.niter_decay> epochs. |
| For other schedulers (step, plateau, and cosine), we use the default PyTorch schedulers. |
| See https://pytorch.org/docs/stable/optim.html for more details. |
| """ |
| if opt.lr_policy == 'linear': |
| def lambda_rule(epoch): |
| lr_l = 1.0 - max(0, epoch + opt.epoch_count - opt.niter) / float(opt.niter_decay + 1) |
| return lr_l |
| scheduler = lr_scheduler.LambdaLR(optimizer, lr_lambda=lambda_rule) |
| elif opt.lr_policy == 'step': |
| scheduler = lr_scheduler.StepLR(optimizer, step_size=opt.lr_decay_iters, gamma=0.1) |
| elif opt.lr_policy == 'plateau': |
| scheduler = lr_scheduler.ReduceLROnPlateau(optimizer, mode='min', factor=0.2, threshold=0.01, patience=5) |
| elif opt.lr_policy == 'cosine': |
| scheduler = lr_scheduler.CosineAnnealingLR(optimizer, T_max=opt.niter, eta_min=0) |
| else: |
| return NotImplementedError('learning rate policy [%s] is not implemented', opt.lr_policy) |
| return scheduler |
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