import copy
import dataclasses
import logging
import os
from typing import Literal, Optional, Sequence, Union
import dacite
import torch
import xarray as xr
import yaml
import fme
import fme.core.logging_utils as logging_utils
from fme.ace.aggregator.inference import InferenceAggregatorConfig
from fme.ace.data_loading.batch_data import (
BatchData,
InferenceGriddedData,
PrognosticState,
)
from fme.ace.data_loading.getters import get_forcing_data
from fme.ace.data_loading.inference import (
ExplicitIndices,
ForcingDataLoaderConfig,
InferenceInitialConditionIndices,
TimestampList,
)
from fme.ace.inference.data_writer import DataWriter, DataWriterConfig
from fme.ace.inference.loop import write_reduced_metrics
from fme.ace.stepper import SingleModuleStepper, SingleModuleStepperConfig
from fme.core.dicts import to_flat_dict
from fme.core.generics.inference import get_record_to_wandb, run_inference
from fme.core.logging_utils import LoggingConfig
from fme.core.ocean import OceanConfig
from fme.core.timing import GlobalTimer
from .evaluator import load_stepper, load_stepper_config, validate_time_coarsen_config
StartIndices = Union[InferenceInitialConditionIndices, ExplicitIndices, TimestampList]
[docs]@dataclasses.dataclass
class InitialConditionConfig:
"""
Configuration for initial conditions.
.. note::
The data specified under path should contain a time dimension of at least
length 1. If multiple times are present in the dataset specified by ``path``,
the inference will start an ensemble simulation using each IC along a
leading sample dimension. Specific times can be selected from the dataset
by using ``start_indices``.
Parameters:
path: The path to the initial conditions dataset.
engine: The engine used to open the dataset.
start_indices: optional specification of the subset of
initial conditions to use.
"""
path: str
engine: Literal["netcdf4", "h5netcdf", "zarr"] = "netcdf4"
start_indices: Optional[StartIndices] = None
def get_dataset(self) -> xr.Dataset:
ds = xr.open_dataset(self.path, engine=self.engine, use_cftime=True)
return self._subselect_initial_conditions(ds)
def _subselect_initial_conditions(self, ds: xr.Dataset) -> xr.Dataset:
if self.start_indices is None:
ic_indices = slice(None, None)
elif isinstance(self.start_indices, TimestampList):
time_index = xr.CFTimeIndex(ds.time.values)
ic_indices = self.start_indices.as_indices(time_index)
else:
ic_indices = self.start_indices.as_indices()
# time is a required variable but not necessarily a dimension
sample_dim_name = ds.time.dims[0]
return ds.isel({sample_dim_name: ic_indices})
def get_initial_condition(
ds: xr.Dataset, prognostic_names: Sequence[str]
) -> PrognosticState:
"""Given a dataset, extract a mapping of variables to tensors.
and the time coordinate corresponding to the initial conditions.
Args:
ds: Dataset containing initial condition data. Must include prognostic_names
as variables, and they must each have shape (n_samples, n_lat, n_lon).
Dataset must also include a 'time' variable with length n_samples.
prognostic_names: Names of prognostic variables to extract from the dataset.
Returns:
The initial condition and the time coordinate.
"""
initial_condition = {}
for name in prognostic_names:
if len(ds[name].shape) != 3:
raise ValueError(
f"Initial condition variables {name} must have shape "
f"(n_samples, n_lat, n_lon). Got shape {ds[name].shape}."
)
n_samples = ds[name].shape[0]
initial_condition[name] = torch.tensor(ds[name].values).unsqueeze(dim=1)
if "time" not in ds:
raise ValueError("Initial condition dataset must have a 'time' variable.")
initial_times = xr.DataArray(
data=ds.time.values[:, None],
dims=["sample", "time"],
)
if initial_times.shape[0] != n_samples:
raise ValueError(
"Length of 'time' variable must match first dimension of variables "
f"in initial condition dataset. Got {initial_times.shape[0]} "
f"and {n_samples}."
)
batch_data = BatchData.new_on_cpu(
data=initial_condition,
time=initial_times,
horizontal_dims=["lat", "lon"],
)
return batch_data.get_start(prognostic_names, n_ic_timesteps=1)
[docs]@dataclasses.dataclass
class InferenceConfig:
"""
Configuration for running inference.
Parameters:
experiment_dir: Directory to save results to.
n_forward_steps: Number of steps to run the model forward for.
checkpoint_path: Path to stepper checkpoint to load.
logging: Configuration for logging.
initial_condition: Configuration for initial condition data.
forcing_loader: Configuration for forcing data.
forward_steps_in_memory: Number of forward steps to complete in memory
at a time.
data_writer: Configuration for data writers.
aggregator: Configuration for inference aggregator.
ocean: Ocean configuration for running inference with a
different one than what is used in training.
"""
experiment_dir: str
n_forward_steps: int
checkpoint_path: str
logging: LoggingConfig
initial_condition: InitialConditionConfig
forcing_loader: ForcingDataLoaderConfig
forward_steps_in_memory: int = 10
data_writer: DataWriterConfig = dataclasses.field(
default_factory=lambda: DataWriterConfig()
)
aggregator: InferenceAggregatorConfig = dataclasses.field(
default_factory=lambda: InferenceAggregatorConfig()
)
ocean: Optional[OceanConfig] = None
def __post_init__(self):
if self.data_writer.time_coarsen is not None:
validate_time_coarsen_config(
self.data_writer.time_coarsen,
self.forward_steps_in_memory,
self.n_forward_steps,
)
def configure_logging(self, log_filename: str):
self.logging.configure_logging(self.experiment_dir, log_filename)
def configure_wandb(self, env_vars: Optional[dict] = None, **kwargs):
config = to_flat_dict(dataclasses.asdict(self))
self.logging.configure_wandb(
config=config, env_vars=env_vars, resume=False, **kwargs
)
def clean_wandb(self):
self.logging.clean_wandb(self.experiment_dir)
def load_stepper(self) -> SingleModuleStepper:
logging.info(f"Loading trained model checkpoint from {self.checkpoint_path}")
stepper = load_stepper(self.checkpoint_path, ocean_config=self.ocean)
return stepper
def load_stepper_config(self) -> SingleModuleStepperConfig:
logging.info(f"Loading trained model checkpoint from {self.checkpoint_path}")
return load_stepper_config(self.checkpoint_path, ocean_config=self.ocean)
def get_data_writer(self, data: InferenceGriddedData) -> DataWriter:
return self.data_writer.build(
experiment_dir=self.experiment_dir,
# each batch contains all samples, for different times
n_initial_conditions=data.n_initial_conditions,
n_timesteps=self.n_forward_steps,
timestep=data.timestep,
variable_metadata=data.variable_metadata,
coords=data.coords,
)
def main(yaml_config: str, segments: Optional[int] = None):
with open(yaml_config, "r") as f:
data = yaml.safe_load(f)
config = dacite.from_dict(
data_class=InferenceConfig,
data=data,
config=dacite.Config(strict=True),
)
if not os.path.isdir(config.experiment_dir):
os.makedirs(config.experiment_dir, exist_ok=True)
with open(os.path.join(config.experiment_dir, "config.yaml"), "w") as f:
yaml.dump(data, f, default_flow_style=False, sort_keys=False)
if segments is None:
with GlobalTimer():
return run_inference_from_config(config)
else:
config.configure_logging(log_filename="inference_out.log")
run_segmented_inference(config, segments)
def run_inference_from_config(config: InferenceConfig):
timer = GlobalTimer.get_instance()
timer.start_outer("inference")
timer.start("initialization")
if not os.path.isdir(config.experiment_dir):
os.makedirs(config.experiment_dir, exist_ok=True)
config.configure_logging(log_filename="inference_out.log")
env_vars = logging_utils.retrieve_env_vars()
beaker_url = logging_utils.log_beaker_url()
config.configure_wandb(env_vars=env_vars, notes=beaker_url)
torch.backends.cudnn.benchmark = True
logging_utils.log_versions()
logging.info(f"Current device is {fme.get_device()}")
stepper_config = config.load_stepper_config()
data_requirements = stepper_config.get_forcing_window_data_requirements(
n_forward_steps=config.forward_steps_in_memory
)
logging.info("Loading initial condition data")
initial_condition = get_initial_condition(
config.initial_condition.get_dataset(), stepper_config.prognostic_names
)
stepper = config.load_stepper()
logging.info("Initializing forcing data loaded")
data = get_forcing_data(
config=config.forcing_loader,
total_forward_steps=config.n_forward_steps,
window_requirements=data_requirements,
initial_condition=initial_condition,
surface_temperature_name=stepper.surface_temperature_name,
ocean_fraction_name=stepper.ocean_fraction_name,
)
if stepper.timestep != data.timestep:
raise ValueError(
f"Timestep of the loaded stepper, {stepper.timestep}, does not "
f"match that of the forcing data, {data.timestep}."
)
aggregator = config.aggregator.build(
gridded_operations=data.gridded_operations,
n_timesteps=config.n_forward_steps + stepper.n_ic_timesteps,
variable_metadata=data.variable_metadata,
)
writer = config.get_data_writer(data)
timer.stop()
logging.info("Starting inference")
record_logs = get_record_to_wandb(label="inference")
run_inference(
predict=stepper.predict,
data=data,
writer=writer,
aggregator=aggregator,
record_logs=record_logs,
)
timer.start("final_writer_flush")
logging.info("Starting final flush of data writer")
writer.flush()
logging.info("Writing reduced metrics to disk in netcdf format.")
write_reduced_metrics(aggregator, data.coords, config.experiment_dir)
timer.stop()
timer.stop_outer("inference")
total_steps = config.n_forward_steps * data.n_initial_conditions
inference_duration = timer.get_duration("inference")
wandb_logging_duration = timer.get_duration("wandb_logging")
total_steps_per_second = total_steps / (inference_duration - wandb_logging_duration)
timer.log_durations()
logging.info(
"Total steps per second (ignoring wandb logging): "
f"{total_steps_per_second:.2f} steps/second"
)
summary_logs = {
"total_steps_per_second": total_steps_per_second,
**timer.get_durations(),
**aggregator.get_summary_logs(),
}
record_logs([summary_logs])
config.clean_wandb()
def run_segmented_inference(config: InferenceConfig, segments: int):
"""Run inference in multiple segments.
Args:
config: inference configuration to be used for each individual segment. The
provided initial condition configuration will only be used for the first
segment.
segments: total number of segments desired. Only missing segments will be run.
Note:
This is useful when running very long simulations or when saving a large
amount of output data to disk. The simulation outputs will be split across
multiple folders, each corresponding to one of the segments and labeled by
the segment number.
"""
logging.info(
f"Starting segmented inference with {segments} segments. "
f"Saving to {config.experiment_dir}."
)
config_copy = copy.deepcopy(config)
original_wandb_name = os.environ.get("WANDB_NAME")
for segment in range(segments):
segment_label = f"segment_{segment:04d}"
segment_dir = os.path.join(config.experiment_dir, segment_label)
restart_path = os.path.join(segment_dir, "restart.nc")
if os.path.exists(restart_path):
logging.info(f"Skipping segment {segment} because it has already been run.")
else:
logging.info(f"Running segment {segment}.")
config_copy.experiment_dir = segment_dir
if original_wandb_name is not None:
os.environ["WANDB_NAME"] = f"{original_wandb_name}-{segment_label}"
with GlobalTimer():
run_inference_from_config(config_copy)
config_copy.initial_condition = InitialConditionConfig(
path=restart_path, engine="netcdf4"
)