atomr 0.9.2

Native Rust actor runtime with Python bindings — supervised concurrency from one core to a cluster.

atomr

A native Rust runtime for actor-based concurrent and distributed systems, with first-class Python bindings. atomr gives you a single mental model — addressable units of state plus behavior, communicating by asynchronous messages — that scales from a single core to a cluster, and increasingly from a CPU to a GPU.

use atomr::prelude::*;

#[derive(Default)]
struct Greeter;

#[async_trait::async_trait]
impl Actor for Greeter {
    type Msg = String;
    async fn handle(&mut self, _ctx: &mut Context<Self>, msg: String) {
        println!("hi {msg}");
    }
}

Why an actor runtime, in Rust, now

The actor model is the same idea wherever it runs: a small, addressable unit of state plus behavior, talking to other actors by asynchronous message passing. That model is a good fit for two converging trends.

Agentic systems. Long-lived, autonomous, collaborating processes that reason, call tools, and coordinate are exactly what supervised, addressable actors describe. Each agent is an actor; conversations are mailboxes; tool calls are typed messages; failure is supervised, not silently swallowed. atomr gives that model a runtime that doesn't trade performance for safety.

Unified compute. Modern workloads no longer live entirely on the CPU. Inference, embedding, scoring, simulation — they want a GPU. Coordination, control flow, I/O, persistence — they want a CPU. Today's stacks force you to glue the two with ad-hoc batching layers, queues, and serialization boundaries. The actor model already encodes the right boundary: a message is the dispatch unit. atomr is built so that the same actor_ref.tell(msg) can target a CPU mailbox today and a CUDA-backed dispatcher tomorrow — with the same supervision, the same backpressure, the same observability. The runtime is explicit about where work runs without forcing the developer to write two programs.

Granular efficiency. Rust gives us deterministic resource use, zero-cost abstractions, and ownership-as-concurrency-safety. Per-message cost stays low. Per-actor footprint stays small. The scheduler can hand work to a tokio worker, a dedicated dispatcher, or — by design — a GPU stream, without changing the message contract. That same precision lets the runtime push backpressure, mailboxes, and supervision down to a level where they don't need to be rebuilt at every layer above.

A longer argument is in docs/actors-and-agentic-computing.md.

What's in the box

Crate	What it does
atomr	Umbrella facade re-exporting the core types
atomr-core	Actors, supervision, dispatch, mailboxes, FSMs, event stream, coordinated shutdown
atomr-config	HOCON-style layered configuration
atomr-macros	Ergonomic derives and helpers
atomr-testkit	Probes, virtual time, deterministic test scaffolding
atomr-remote	Location-transparent messaging across processes (TCP + framed PDU + reliable delivery)
atomr-cluster	Membership, gossip, reachability, split-brain resolution
atomr-cluster-tools	Singleton, pub/sub, cluster-client patterns
atomr-cluster-sharding	Shard regions, rebalance, remember-entities, persistent coordinator
atomr-cluster-metrics	Adaptive load balancing
atomr-distributed-data	Convergent replicated data types (CRDTs) over the cluster — OrMap, LWWMap, PNCounterMap, ORMultiMap, replicator subscribe
atomr-distributed-data-lmdb	redb-backed DurableStore for distributed-data
atomr-persistence	Event sourcing — journals, snapshots, recovery, async snapshotting, persistent FSM, ALOD
atomr-persistence-query	Tagged event streams over journals
atomr-persistence-query-inmemory	In-memory query journal for tests + samples
atomr-persistence-{sql,redis,mongodb,cassandra,aws,azure}	Storage adapters (Postgres / MySQL / Redis / Mongo / Cassandra / DynamoDB / Azurite)
atomr-persistence-tck	Conformance suite — journal_replay_edge_cases, snapshot_extended_suite, concurrent + extended journal suites
atomr-streams	Typed reactive streams (sources, flows, sinks, junctions, hubs, kill switches, sub-streams, conflate/expand, merge_sorted/merge_prioritized, queue/restart)
atomr-serialization-hyperion	Hyperion-compatible serializer surface
atomr-coordination	Lease-based leadership primitives
atomr-discovery	Pluggable service discovery
atomr-di	Dependency-injection container
atomr-hosting	Builder API for wiring system + config + DI together
atomr-telemetry	Tracing, metrics, exporters
atomr-dashboard	Live web UI over the running system

Plus a Python facade — pip install atomr — that exposes the full actor model: real Context (children, watch, stash, become, timers, sender), configurable SupervisorStrategy with retry-budget enforcement, routers and resilience patterns, multi-node TCP + in-process cluster transports with per-system codec registries, event-sourced actors, the full distributed-data CRDT suite + Replicator, real ShardRegion with allocation/passivation/remember- entities, the streams DSL on arbitrary Python objects, and GIL-isolated interpreter pools for CPU-bound work.

Test coverage

atomr ships ~545 lib tests plus ~420 integration tests across the workspace. Subsystem coverage includes:

• Cluster. Vector clock, member ordering, reachability, cluster events, gossip, SBR strategies, heartbeat, membership state, plus a LeaderHandover watcher and a multinode harness.
• Cluster tools / sharding. Singleton, ClusterClient, distributed PubSub, shard allocation + handoff, at-least-once-delivery.
• Distributed data. OrMap / LWWMap / PNCounterMap / ORMultiMap, CRDT laws, replicator subscribe, three-node convergence suites, redb-backed durable store (atomr-distributed-data-lmdb).
• Persistence. PersistentFSM, EventSourced, ALOD, snapshot retention, plus the TCK's journal_replay_edge_cases and snapshot_extended_suite exercised against every backend (Postgres, MySQL, Redis, MongoDB, Cassandra, DynamoDB, Azurite, redb) in CI.
• Streams. FlowOperator, Hub, SubStream, Recovery, conflate / expand, merge_sorted / merge_prioritized, Queue / Restart.
• Core runtime. Scheduler, Stash, Extensions, Lifecycle, IO managers (TcpManager outbound Connect + IO coverage), ActorPath / Address, FailureDetector, EndpointState, Routing.
• Hosting / DI / lease. ServiceContainer, Hosting builder, Lease.
• Out-of-process multinode. MultiNodeOopController and MultiNodeOopNode drive cross-process scenarios from the testkit.

Quick start (Rust)

The umbrella crate is published on crates.io as atomr:

[dependencies]
atomr = { version = "0.1", features = ["cluster", "persistence"] }

Or pull in subsystem crates directly — atomr-core, atomr-cluster, atomr-persistence, atomr-streams, etc. are all on crates.io.

use atomr::prelude::*;

#[derive(Default)]
struct Greeter;

#[async_trait::async_trait]
impl Actor for Greeter {
    type Msg = String;
    async fn handle(&mut self, _ctx: &mut Context<Self>, msg: String) {
        println!("hi {msg}");
    }
}

# async fn run() -> Result<(), Box<dyn std::error::Error>> {
let system = ActorSystem::create("S", Config::empty()).await?;
let greeter = system.actor_of(Props::create(Greeter::default), "greeter")?;
greeter.tell("world".to_string());
system.terminate().await;
# Ok(()) }

Quick start (Python)

python -m venv .venv && source .venv/bin/activate
pip install atomr

from atomr import Actor, ActorSystem, props

class Greeter(Actor):
    async def handle(self, ctx, msg):
        return f"hello, {msg}"

system = ActorSystem.create_blocking("app")
ref = system.actor_of(props(Greeter), "greeter")
print(ref.ask_blocking("world", timeout=5.0))   # -> "hello, world"
system.terminate_blocking()

handle(ctx, msg) receives a real Context — ctx.spawn(props, name), ctx.watch(ref), ctx.stash(msg), ctx.become(handler), ctx.schedule_once(0.5, "tick") (returns a Cancelable), ctx.sender, etc. Two systems can join a cluster over TCP or an in-process registry, exchange messages via per-system codec registries, and run sharded entity actors:

from atomr.cluster import Cluster, ClusterRegistry

ca = Cluster.with_tcp_transport(sys_a, "127.0.0.1:0")
cb = Cluster.with_tcp_transport(sys_b, "127.0.0.1:0")
sys_a.register_codec("json", encode, decode, manifests=["app.MyMsg"])
sys_a.tell_remote(remote_ref, MyMsg(...))

See docs/python.md for the full guide: distributed actors, supervision, patterns + routers, sharding, event sourcing, distributed data, streams DSL, GIL strategies (python-pinned, python-subinterpreter-pool per PEP 684, python-nogil per PEP 703, python-subprocess), and the C-extension compatibility registry. The Python suite ships with 270 tests including TCP and in-process multi-node cluster, sharding, and replicator integration tests.

Building from source

# Rust
cargo build --workspace
cargo test --workspace

# Python bindings (requires maturin + a Python dev toolchain)
maturin develop --release
pytest python/tests -v

# Docs (optional)
pip install mkdocs-material
mkdocs serve

Profiling

atomr ships with a cross-runtime profiler that measures the same four scenarios (tell, ask, fanout, cpu) in Rust and Python and emits a shared JSON schema so the two paths can be compared directly.

cargo run --release -p atomr-profiler -- --scenario all --format md
python -m atomr.profiler --scenario all --format md

See docs/profiler.md.

Layout

crates/                 Rust workspace
crates/py-bindings/     PyO3 bridge crates
python/atomr/           Python package
python/tests/           Python integration tests
examples/               Runnable Rust examples
benches/                Criterion benches
scripts/                Cross-runtime tooling
docs/                   mkdocs-material source
xtask/                  Cargo xtask (audit, profile, bump, verify)

Learn more

• docs/actors-and-agentic-computing.md — the case for actors as the substrate for agentic + heterogeneous compute.
• docs/architecture.md — runtime structure.
• docs/idiomatic-rust.md — design choices.
• docs/python.md — Python bindings + GIL strategies.
• docs/remoting.md — cross-process actor remoting.
• docs/persistence-providers.md — storage adapters.
• docs/dashboard.md — live system UI.
• docs/observability.md — tracing + metrics exporters.
• docs/profiler.md — cross-runtime profiler.
• docs/alignment-ledger.md — crate-by-crate alignment of the runtime surface.
• docs/depth-roadmap.md — depth roadmap.