nvalchemi-training-api
How to configure nvalchemi training workflows with TrainingStrategy, custom training functions, standalone or composed losses, loss-weight schedules, optimizer…
npx skills add https://github.com/nvidia/nvalchemi-toolkit --skill nvalchemi-training-apinvalchemi Training API
Overview
Use TrainingStrategy as the owner of one training job: model(s), dataloaders,
loss, optimizer/scheduler config, validation, hooks, runtime counters, and
checkpoints. For full details, link agents to docs/userguide/training.md,
docs/userguide/losses.md, and docs/modules/training/checkpoints.rst.
import torch
from nvalchemi.data import Batch
from nvalchemi.models.base import BaseModelMixin
from nvalchemi.training import (
CheckpointHook,
ComposedLossFunction,
CosineWeight,
EnergyMSELoss,
ForceMSELoss,
LinearWeight,
OptimizerConfig,
StressMSELoss,
TrainingStrategy,
ValidationConfig,
create_model_spec,
)
Minimal Pattern
loss_fn = ComposedLossFunction(
[EnergyMSELoss(), ForceMSELoss()],
weights=[1.0, 10.0],
normalize_weights=False,
)
strategy = TrainingStrategy(
models=model,
optimizer_configs=OptimizerConfig(
optimizer_cls=torch.optim.AdamW,
optimizer_kwargs={"lr": 1e-4, "weight_decay": 1e-5},
),
loss_fn=loss_fn,
validation_config=ValidationConfig(validation_data=val_loader, every_n_epochs=1),
hooks=[CheckpointHook("runs/example/checkpoints", epoch_interval=1)],
num_epochs=20,
)
strategy.run(train_loader)
Model-Agnostic Inputs
Accept any torch.nn.Module that works with the selected training_fn. Prefer
wrapped BaseModelMixin models for standard AtomicData/Batch contracts;
load nvalchemi-model-wrapping or docs/userguide/models.md when adapting
arbitrary MLIPs.
Make model construction reproducible when possible. Use native checkpoint
constructors that carry a spec, or store a create_model_spec(...) for custom
wrappers so strategy checkpoints can rebuild the model before loading weights.
Treat foreign checkpoints as imported weights until a fresh TrainingStrategy
checkpoint has been saved.
Custom Training Functions
Use training_fn when the batch needs custom routing, multiple models, teacher
outputs, auxiliary predictions, or non-standard model outputs. It receives
(model, batch) for a single model or (models, batch) for named models and
returns the prediction mapping consumed by loss_fn.
For multiple models, pass a named mapping. optimizer_configs must use the same
model keys for trainable models. Models absent from optimizer_configs may be
used in the forward path but are frozen during training.
def training_fn(models: dict[str, BaseModelMixin], batch: Batch):
student = models["student"](batch)
with torch.no_grad():
teacher = models["teacher"](batch)
return {
"student_energy": student["energy"],
"teacher_energy": teacher["energy"].detach(),
}
loss_fn = ComposedLossFunction(
[EnergyMSELoss(prediction_key="student_energy", target_key="teacher_energy")]
)
strategy = TrainingStrategy(
models={"student": student_model, "teacher": teacher_model},
optimizer_configs={
"student": [
OptimizerConfig(
optimizer_cls=torch.optim.AdamW,
optimizer_kwargs={"lr": 3e-5},
)
]
},
training_fn=training_fn,
loss_fn=loss_fn,
num_epochs=5,
)
If targets do not come directly from the batch, also provide a
loss_target_assembler; see docs/userguide/training.md.
Losses And Scheduling
A standalone leaf loss such as EnergyMSELoss() can be used when the objective
has one target. Use ComposedLossFunction or operator sugar for multi-target
objectives. Leaf losses consume unweighted tensors; weights and schedules live on
the composition. Built-in schedules include ConstantWeight, LinearWeight,
CosineWeight, and PiecewiseWeight.
Built-in losses default to dtype_policy="strict" and raise when prediction
and target dtypes differ. When building or reviewing workflows, check likely
label/model dtype alignment, such as float64 dataset labels with float32 model
outputs. If the mismatch is intentional, tell the user they can set
dtype_policy="prediction_to_target" to cast outputs to labels or
dtype_policy="target_to_prediction" to cast labels to outputs. Set the
policy on an explicit ComposedLossFunction(...), on a leaf loss, or after
operator-sugar construction:
loss_fn = EnergyMSELoss() + ForceMSELoss()
loss_fn.dtype_policy = "prediction_to_target"
A leaf loss with its own explicit dtype_policy overrides the composed-level
policy. The setting is included in serializable loss specs for restartable
training workflows. For CLI scaffolds, pass --loss-dtype-policy strict,
--loss-dtype-policy prediction_to_target, or
--loss-dtype-policy target_to_prediction to nvalchemi-training train init
or nvalchemi-training finetune init ...; spec report shows the selected
policy.
loss_fn = (
1.0 * EnergyMSELoss()
+ LinearWeight(start=0.0, end=10.0, num_steps=1000) * ForceMSELoss()
+ CosineWeight(start=0.0, end=0.1, num_steps=5000) * StressMSELoss()
)
Caveats:
normalize_weights=Trueis the default; setFalsefor raw coefficient sums.per_epoch=Trueschedules requireepochduring loss calls.- Custom schedules must implement
per_epoch,__call__(step, epoch), andto_spec()if they are used in restartable strategy checkpoints. - For custom leaf-loss internals, use
nvalchemi-loss-apianddocs/userguide/losses.md.
Optimizers And Schedulers
Use OptimizerConfig(optimizer_cls=..., optimizer_kwargs=...); add
scheduler_cls and scheduler_kwargs when needed. Keyword arguments are
validated against class constructors before training starts.
Time-based schedulers step after optimizer steps. ReduceLROnPlateau-style
metric schedulers step after validation; set scheduler_metric_adapter to a
validation-summary key or callable when the default "total_loss" is not right.
Checkpoints And Reproducibility
Agent-created training workflows should be fully checkpointable and reproducible:
- Use deterministic model/wrapper constructors or
create_model_spec(...). - Keep loss functions, schedules, optimizer configs, and restart-critical hooks
serializable; implement
to_spec()where protocols require it. - Use
CheckpointHookfor periodic checkpoints and save early enough for preempted jobs, including Slurm-style cluster runs. - Make data splits, sampler state, seeds, units, dtype/device choices, and config files explicit in the run directory.
Strategy checkpoints are restart packages: model weights, optimizer and scheduler state, strategy counters, checkpointable hook state, and reconstruction metadata.
Resume Training
Use resume when continuing the same run after interruption. This is different from fine-tuning, which imports weights into a new objective or dataset.
strategy = TrainingStrategy.load_checkpoint("runs/example/checkpoints", map_location="cuda")
strategy.run(train_loader)
Resume only from native TrainingStrategy checkpoints when optimizer, scheduler,
hook state, and counters matter. Plain pretrained weight files are not sufficient
for faithful continuation. To start a fresh fine-tuning run from native
checkpoint weights, use FineTuningStrategy.from_pretrained_checkpoint(...) from
nvalchemi-fine-tuning; opt into source loss or optimizer classes with
use_original_loss=True or use_original_opt_class=True when those defaults are
desired. See docs/modules/training/checkpoints.rst.