nvalchemi-dynamics-hooks
How to use and write dynamics hooks — callbacks that observe or modify batch state at specific points during each simulation step. Use when a simulation needs…
npx skills add https://github.com/nvidia/nvalchemi-toolkit --skill nvalchemi-dynamics-hooksnvalchemi Hooks
Overview
Hooks are callbacks that fire at specific points during each workflow step.
They observe or modify batch state without changing the engine itself.
The hook system is framework-wide: the same Hook protocol works for
dynamics and custom pipelines. Dynamics engines pass DynamicsContext;
custom engines can pass HookContext or their own context subclass.
from nvalchemi.hooks import (
BiasedPotentialHook,
DynamicsContext,
Hook,
HookContext,
HookRegistryMixin,
NeighborListHook,
WrapPeriodicHook,
)
from nvalchemi.dynamics.base import DynamicsStage
from nvalchemi.dynamics.hooks import (
EnergyDriftMonitorHook,
LoggingHook,
MaxForceClampHook,
NaNDetectorHook,
ProfilerHook,
SnapshotHook,
)
Hook protocol
Any object with these attributes satisfies the Hook protocol (runtime-checkable):
class Hook(Protocol):
frequency: int # execute every N steps (1 = every step)
stage: Enum | None # stage enum value (None for stage-agnostic hooks)
def __call__(self, ctx: HookContext, stage: Enum) -> None:
"""Called with a context snapshot and the current stage."""
...
A hook fires when step_count % hook.frequency == 0 (so all hooks fire at
step 0).
HookContext — base snapshot shared by hook-enabled workflows:
@dataclass(kw_only=True)
class HookContext:
batch: Batch # current batch (all engines)
model: BaseModelMixin | None = None
global_rank: int = 0 # distributed rank
workflow: Any = None # back-reference to the engine
DynamicsContext — context passed by dynamics engines:
@dataclass(kw_only=True)
class DynamicsContext(HookContext):
step_count: int = 0
converged_mask: torch.Tensor | None = None
Access batch data via ctx.batch and dynamics step info via ctx.step_count.
Execution stages
Dynamics — DynamicsStage
Each step() call fires hooks at 9 stages in this order:
BEFORE_STEP (0)
BEFORE_PRE_UPDATE (1) → pre_update() → AFTER_PRE_UPDATE (2)
BEFORE_COMPUTE (3) → compute() → AFTER_COMPUTE (4)
BEFORE_POST_UPDATE (5) → post_update() → AFTER_POST_UPDATE (6)
AFTER_STEP (7)
ON_CONVERGE (8) ← only if convergence detected
Stage selection guidelines (dynamics):
| Goal | Stage |
|---|---|
| Modify forces/energy after model | DynamicsStage.AFTER_COMPUTE |
| Observe final state (logging, snapshots) | DynamicsStage.AFTER_STEP |
| Wrap positions after velocity update | DynamicsStage.AFTER_POST_UPDATE |
| Instrument timing / profiling | DynamicsStage.BEFORE_STEP |
| React to convergence | DynamicsStage.ON_CONVERGE |
Registering hooks
from nvalchemi.dynamics.demo import DemoDynamics
# At construction
dynamics = DemoDynamics(
model=model,
n_steps=1000,
dt=0.5,
hooks=[
MaxForceClampHook(max_force=10.0),
LoggingHook(frequency=100),
],
)
# After construction
dynamics.register_hook(NaNDetectorHook(frequency=10))
Multiple hooks at the same stage fire in registration order.
Stage type enforcement: each engine declares _stage_type to restrict
which enum types are accepted. For example, BaseDynamics sets
_stage_type = DynamicsStage.
Built-in hooks
Safety hooks (stage: AFTER_COMPUTE)
NaNDetectorHook — detect NaN/Inf in forces and energy.
NaNDetectorHook(
frequency=1, # check every N steps
extra_keys=["stress"], # additional batch keys to check (optional)
)
MaxForceClampHook — clamp per-atom force vectors to a maximum L2 norm.
MaxForceClampHook(
max_force=10.0, # max force norm (eV/A)
frequency=1,
)
Bias hook (stage: AFTER_COMPUTE)
BiasedPotentialHook — add an external bias potential for enhanced sampling.
def my_bias(batch: Batch) -> tuple[torch.Tensor, torch.Tensor]:
"""Return (bias_energy [B, 1], bias_forces [V, 3])."""
bias_e = torch.zeros(batch.num_graphs, 1, device=batch.device)
bias_f = torch.zeros_like(batch.positions)
# ... compute bias ...
return bias_e, bias_f
BiasedPotentialHook(
bias_fn=my_bias,
stage=DynamicsStage.AFTER_COMPUTE,
frequency=1,
)
Observer hooks (stage: AFTER_STEP)
LoggingHook — log scalar observables.
LoggingHook(
backend="csv", # "csv", "tensorboard", or "custom"
frequency=100,
log_path="md_log.csv", # for file-based backends
custom_scalars={ # additional scalars to log
"max_velocity": lambda ctx: ctx.batch.velocities.norm(dim=-1).max(),
},
writer_fn=None, # custom writer for "custom" backend
)
SnapshotHook — save full batch state to a DataSink.
from nvalchemi.dynamics.sinks import GPUBuffer, HostMemory, ZarrData
SnapshotHook(
sink=ZarrData("trajectory.zarr", capacity=10000),
frequency=10,
)
EnergyDriftMonitorHook — track total energy drift.
EnergyDriftMonitorHook(
threshold=1e-4, # drift threshold
metric="per_atom_per_step", # or "absolute"
action="warn", # or "raise"
frequency=1,
include_kinetic=True, # include kinetic energy
)
Periodic boundary hook (stage: AFTER_POST_UPDATE)
WrapPeriodicHook — wrap positions back into the unit cell.
WrapPeriodicHook(frequency=10, stage=DynamicsStage.AFTER_POST_UPDATE)
Profiling hook (multi-stage, uses plum dispatch)
ProfilerHook — NVTX ranges and wall-clock timing. Fires at multiple
stages via _runs_on_stage and uses plum.dispatch to support
dynamics and custom workflows with appropriate domain annotations.
ProfilerHook(
profiled_stages="all", # "all", "step", or "detailed"
frequency=1,
enable_nvtx=True, # NVTX annotation for Nsight Systems
timer_backend="auto", # "auto", "cuda_event", or "perf_counter"
)
Writing a custom hook
Option 1: Simple single-stage hook (dynamics)
Implement the protocol directly — no inheritance needed.
from nvalchemi.dynamics.base import DynamicsStage
from nvalchemi.hooks import DynamicsContext
class TemperatureLogger:
stage = DynamicsStage.AFTER_STEP
frequency = 50
def __call__(self, ctx: DynamicsContext, stage: DynamicsStage) -> None:
ke = ctx.batch.kinetic_energies.sum()
n_atoms = ctx.batch.num_nodes
temp = 2.0 * ke / (3.0 * n_atoms * 8.617e-5) # kB in eV/K
print(f"Step {ctx.step_count}: T = {temp:.1f} K")
Option 2: Multi-stage hook with _runs_on_stage
Fire at multiple stages by defining _runs_on_stage(stage) -> bool:
from enum import Enum
from nvalchemi.dynamics.base import DynamicsStage
from nvalchemi.hooks import DynamicsContext
class StepTimerHook:
stage = DynamicsStage.BEFORE_STEP # primary stage (protocol compliance)
frequency = 1
def __init__(self):
self._stages = {DynamicsStage.BEFORE_STEP, DynamicsStage.AFTER_STEP}
self._t0 = None
def _runs_on_stage(self, stage: Enum) -> bool:
return stage in self._stages
def __call__(self, ctx: DynamicsContext, stage: DynamicsStage) -> None:
import time
if stage == DynamicsStage.BEFORE_STEP:
self._t0 = time.perf_counter()
elif stage == DynamicsStage.AFTER_STEP and self._t0 is not None:
dt = time.perf_counter() - self._t0
print(f"Step {ctx.step_count}: {dt*1000:.1f} ms")
Option 3: Cross-category hook with plum dispatch
For hooks that work with multiple stage enum types (e.g. DynamicsStage and
a custom enum), use plum.dispatch to overload __call__ with different
stage types:
from dataclasses import dataclass
from enum import Enum
from plum import dispatch
from nvalchemi.dynamics.base import DynamicsStage
from nvalchemi.hooks import DynamicsContext, HookContext
# Example custom stage enum for a hypothetical pipeline
class MyPipelineStage(Enum):
BEFORE_PROCESS = 0
AFTER_PROCESS = 1
@dataclass(kw_only=True)
class PipelineContext(HookContext):
step_count: int = 0
class UniversalLoggerHook:
stage = DynamicsStage.AFTER_STEP
frequency = 10
def __init__(self):
self._stages = {DynamicsStage.AFTER_STEP, MyPipelineStage.AFTER_PROCESS}
def _runs_on_stage(self, stage: Enum) -> bool:
return stage in self._stages
@dispatch
def __call__(self, ctx: DynamicsContext, stage: DynamicsStage) -> None:
fmax = ctx.batch.forces.norm(dim=-1).max().item()
print(f"[dynamics] step {ctx.step_count}: fmax={fmax:.4f}")
@dispatch
def __call__(self, ctx: PipelineContext, stage: MyPipelineStage) -> None:
print(f"[pipeline] step {ctx.step_count}: processed")
@dispatch
def __call__(self, ctx: HookContext, stage: Enum) -> None:
print(f"[custom] stage={stage.name}, graphs={ctx.batch.num_graphs}")
The built-in ProfilerHook uses exactly this pattern to instrument
dynamics and custom workflows with appropriate NVTX domain annotations.
Hook ordering recommendations
Register hooks in this order for correct behavior:
hooks = [
# 1. Bias (modifies forces/energy)
BiasedPotentialHook(bias_fn=my_bias, stage=DynamicsStage.AFTER_COMPUTE),
# 2. Safety (clamp after all force modifications)
MaxForceClampHook(max_force=10.0),
# 3. NaN detection (check final forces)
NaNDetectorHook(),
# 4. Periodic wrapping
WrapPeriodicHook(frequency=10, stage=DynamicsStage.AFTER_POST_UPDATE),
# 5. Observers (read final state)
LoggingHook(frequency=100),
SnapshotHook(sink=my_sink, frequency=50),
EnergyDriftMonitorHook(threshold=1e-4),
# 6. Profiling
ProfilerHook(),
]
dynamics = DemoDynamics(model=model, n_steps=10000, dt=0.5, hooks=hooks)
Complete example
import torch
from nvalchemi.data import AtomicData, Batch
from nvalchemi.models.demo import DemoModel, DemoModelWrapper
from nvalchemi.dynamics.demo import DemoDynamics
from nvalchemi.dynamics.base import DynamicsStage
from nvalchemi.hooks import DynamicsContext
from nvalchemi.dynamics.hooks import MaxForceClampHook, NaNDetectorHook
# Custom hook
class StepPrinter:
stage = DynamicsStage.AFTER_STEP
frequency = 10
def __call__(self, ctx: DynamicsContext, stage: DynamicsStage) -> None:
fmax = ctx.batch.forces.norm(dim=-1).max().item()
print(f"Step {ctx.step_count}: fmax={fmax:.4f}")
# Setup
model = DemoModelWrapper(DemoModel())
dynamics = DemoDynamics(
model=model,
n_steps=100,
dt=0.5,
hooks=[
MaxForceClampHook(max_force=10.0),
NaNDetectorHook(),
StepPrinter(),
],
)
data = AtomicData(
atomic_numbers=torch.tensor([6, 6, 8], dtype=torch.long),
positions=torch.randn(3, 3),
)
batch = Batch.from_data_list([data])
batch.forces = torch.zeros(3, 3)
batch.energy = torch.zeros(1, 1)
dynamics.run(batch)