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import numpy as np
import math
import sys
from typing import Iterable, Optional
import torch
from dataset import score
import utils
from scipy.special import softmax
from dataset import utils_data, score
from einops import rearrange
from torch import nn
import torch.nn.functional as F
import matplotlib.pyplot as plt
import matplotlib.patches as patches
from aurora import Batch, Metadata
from aurora.normalisation import normalise_surf_var, normalise_atmos_var, unnormalise_surf_var, unnormalise_atmos_var
from datetime import timedelta
import pandas as pd
def train_one_epoch_postprocess(model: torch.nn.Module,
data_loader: Iterable, optimizer: torch.optim.Optimizer,
device: torch.device, epoch: int, loss_scaler, max_norm: float = 0,
log_writer=None, start_steps=None, lr_schedule_values=None, wd_schedule_values=None,
num_training_steps_per_epoch=None, update_freq=None,
lat = None, lon = None, level = None, static_vars = None, surf_vars=None, upper_vars=None, model_name="Aurora", criterion=None,
out_surf_vars = None, out_upper_vars = None, out_upper_level = None,use_ours=False, total_step=None):
model.train(True)
metric_logger = utils.MetricLogger(delimiter=" ")
metric_logger.add_meter('lr', utils.SmoothedValue(window_size=1, fmt='{value:.6f}'))
metric_logger.add_meter('min_lr', utils.SmoothedValue(window_size=1, fmt='{value:.6f}'))
header = 'Epoch: [{}]'.format(epoch)
print_freq = 10
optimizer.zero_grad()
for data_iter_step, batch in enumerate(metric_logger.log_every(data_loader, print_freq, header)):
step = data_iter_step // update_freq
if step >= num_training_steps_per_epoch:
continue
it = start_steps + step # global training iteration
# Update LR & WD for the first acc
if lr_schedule_values is not None or wd_schedule_values is not None and data_iter_step % update_freq == 0:
for i, param_group in enumerate(optimizer.param_groups):
if lr_schedule_values is not None:
param_group["lr"] = lr_schedule_values[it] * param_group["lr_scale"]
if wd_schedule_values is not None and param_group["weight_decay"] > 0:
param_group["weight_decay"] = wd_schedule_values[it]
surface, upper, surface_scale, surface_targets, upper_scale, upper_targets, time_points = batch
B, T, V, C, H, W = upper.shape
_, _, V1, _, _ = surface.shape
time_points = [pd.Timestamp(point.item(), unit='ns') for point in time_points[0]]
sfc_weight = [14, 7, 7]
pl_weight = [8, 0.1]
batch = Batch(
surf_vars={
var:surface[:,:,i] for i, var in enumerate(surf_vars)
},
static_vars = static_vars,
atmos_vars={
var:upper[:,:,i] for i, var in enumerate(upper_vars)
},
metadata=Metadata(
lat=lat,
lon=lon,
time=time_points,
atmos_levels=level,
),
).to(device)
pred_surface, pred_upper = model(batch)
del batch
surface_scale, surface_targets, upper_scale, upper_targets = surface_scale.to(device), surface_targets.to(device), upper_scale.to(device), upper_targets.to(device)
loss_surs = 0.0
loss_upps = 0.0
if out_surf_vars:
for i, var in enumerate(out_surf_vars):
mu_surface = pred_surface[:, i*2] * surface_scale[:,1,i] + surface_scale[:,0,i]
sigma_surface = torch.exp(pred_surface[:, i*2+1]) * surface_scale[:,1,i]
loss_sur = criterion(mu_surface, sigma_surface, surface_targets[:,i]) * sfc_weight[i]
metric_logger.meters[f"CRPS_{var}"].update(loss_sur.item(), n=B)
loss_surs += loss_sur
if out_upper_vars:
for i, var in enumerate(out_upper_vars):
mu_upper = pred_upper[:,i*2, level.index(out_upper_level[i])] * upper_scale[:,1,i] + upper_scale[:,0,i]
sigma_upper = torch.exp(pred_upper[:, i*2+1, level.index(out_upper_level[i])]) * upper_scale[:,1,i]
loss_upp = criterion(mu_upper, sigma_upper, upper_targets[:,i]) * pl_weight[i]
metric_logger.meters[f'CRPS_{var}{str(out_upper_level[i])}'].update(loss_upp.item(), n=B)
loss_upps += loss_upp
loss = loss_surs + loss_upps
loss_value = loss.item()
if math.isnan(loss_value) or math.isinf(loss_value):
print(f"Loss is NaN or Inf at {time_points[0]}")
# this attribute is added by timm on one optimizer (adahessian)
is_second_order = hasattr(optimizer, 'is_second_order') and optimizer.is_second_order
loss /= update_freq
grad_norm = loss_scaler(loss, optimizer, clip_grad=max_norm,
parameters=model.parameters(), create_graph=is_second_order,
update_grad=(data_iter_step + 1) % update_freq == 0,use_ours=use_ours, weight=0.2*(1-it/total_step), k_value=0.001)
if (data_iter_step + 1) % update_freq == 0:
optimizer.zero_grad()
loss_scale_value = loss_scaler.state_dict()["scale"]
torch.cuda.synchronize()
metric_logger.update(loss=loss_value)
metric_logger.update(loss_scale=loss_scale_value)
min_lr = 10.
max_lr = 0.
for group in optimizer.param_groups:
min_lr = min(min_lr, group["lr"])
max_lr = max(max_lr, group["lr"])
metric_logger.update(lr=max_lr)
metric_logger.update(min_lr=min_lr)
weight_decay_value = None
for group in optimizer.param_groups:
if group["weight_decay"] > 0:
weight_decay_value = group["weight_decay"]
metric_logger.update(weight_decay=weight_decay_value)
metric_logger.update(grad_norm=grad_norm)
if log_writer is not None:
log_writer.update(loss=loss_value, head="loss")
log_writer.update(loss_scale=loss_scale_value, head="opt")
log_writer.update(lr=max_lr, head="opt")
log_writer.update(min_lr=min_lr, head="opt")
log_writer.update(weight_decay=weight_decay_value, head="opt")
log_writer.update(grad_norm=grad_norm, head="opt")
log_writer.set_step()
# gather the stats from all processes
metric_logger.synchronize_between_processes()
print("Averaged stats:", metric_logger)
return {k: meter.global_avg for k, meter in metric_logger.meters.items()}
def validation_one_epoch_postprocess(data_loader, model, device, lat = None, lon = None, level = None, criterion1=None, criterion2=None,
static_vars = None, surf_vars=None, upper_vars=None, model_name="Aurora", surface_efis= None, upper_efis = None,
out_surf_vars = None, out_upper_vars = None, out_upper_level = None,):
metric_logger = utils.MetricLogger(delimiter=" ")
header = 'Val:'
# switch to evaluation mode
model.eval()
for batch in metric_logger.log_every(data_loader, 20, header):
surface, upper, surface_scale, surface_targets, upper_scale, upper_targets, time_points = batch
B, T, V, C, H, W = upper.shape
time_points = [pd.Timestamp(point.item(), unit='ns') for point in time_points[0]]
loss_sur = []
loss_upp = []
efi_sur = []
efi_upp = []
batch = Batch(
surf_vars={
var:surface[:,:,i] for i, var in enumerate(surf_vars)
},
static_vars = static_vars,
atmos_vars={
var:upper[:,:,i] for i, var in enumerate(upper_vars)
},
metadata=Metadata(
lat=lat,
lon=lon,
time=time_points,
atmos_levels=level,
),
).to(device)
with torch.inference_mode():
pred_surface, pred_upper = model(batch)
surface_scale, surface_targets, upper_scale, upper_targets = surface_scale.to(device), surface_targets.to(device), upper_scale.to(device), upper_targets.to(device)
if out_surf_vars:
for i, var in enumerate(out_surf_vars):
mu_surface = pred_surface[:, i*2] * surface_scale[:,1,i] + surface_scale[:,0,i]
sigma_surface = torch.exp(pred_surface[:, i*2+1]) * surface_scale[:,1,i]
crps = criterion1(mu_surface, sigma_surface, surface_targets[:,i])
loss_sur.append(crps)
test_loss_efi = []
for j in range(len(time_points)):
# try:
date = time_points[j]
ds_efi = surface_efis[i]
efi_tensor = torch.as_tensor(ds_efi.sel(time=date)["efi"].values)[:-1].to(device)
loss_efi = criterion2(mu_surface[j], sigma_surface[j], surface_targets[j,i], efi_tensor)
test_loss_efi.append(loss_efi.item())
# except KeyError:
# pass
efi_sur.append(np.mean(test_loss_efi))
if out_upper_vars:
for i, var in enumerate(out_upper_vars):
mu_upper = pred_upper[:,i*2, level.index(out_upper_level[i])] * upper_scale[:,1,i] + upper_scale[:,0,i]
sigma_upper = torch.exp(pred_upper[:, i*2+1, level.index(out_upper_level[i])]) * upper_scale[:,1,i]
loss_upp.append(criterion1(mu_upper, sigma_upper, upper_targets[:,i]))
test_loss_efi = []
for j in range(len(time_points)):
date = time_points[j]
ds_efi = upper_efis[i]
efi_tensor = torch.as_tensor(ds_efi.sel(time=date)["efi"].values)[:-1].to(device)
loss_efi = criterion2(mu_upper[j], sigma_upper[j], upper_targets[j,i], efi_tensor)
test_loss_efi.append(loss_efi.item())
efi_upp.append(np.mean(test_loss_efi))
B = surface.shape[0]
for i, var in enumerate(out_surf_vars):
metric_logger.meters[f'CRPS_{var}'].update(loss_sur[i].item(), n=B)
metric_logger.meters[f'EECRPS_{var}'].update(efi_sur[i].item(), n=B)
for i, var in enumerate(out_upper_vars):
metric_logger.meters[f'CRPS_{var}{str(out_upper_level[i])}'].update(loss_upp[i].item(), n=B)
metric_logger.meters[f'EECRPS_{var}{str(out_upper_level[i])}'].update(efi_upp[i].item(), n=B)
# gather the stats from all processes
metric_logger.synchronize_between_processes()
print()
print("Metric:")
print(metric_logger)
print()
return {k: meter.global_avg for k, meter in metric_logger.meters.items()}
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