The motivating end-to-end demonstration (fed-sx-triggers-loop.md Phase 4): one trigger arriving in the pipeline drives a multi-step business flow with a branch, a timer suspension, an injected effect, and a follow-up activity emit — all in the kernel's own runtime. - flow.erl: flow:wait/1 — a timer-style suspend that PRESERVES the value on resume (vs flow:suspend/1, which returns the logged result), so a "wait until morning" step lets the env flow through to later steps. - next/flow/flows/blog_publish_digest.erl: the flow. Branches on the article :category (newsletter -> wait-until-morning -> send + emit; urgent -> send + emit now; else -> skip), fetches followers (injected), builds a digest email per follower, and emits a DigestSent activity OBJECT. Effect-as-data: a flow can't call kernel gen_servers from inside the drive (a blocking call there deadlocks the scheduler), so it returns the emails + DigestSent object for a driver to dispatch and append — which can then trigger downstream flows, closing the loop. Test: triggers_e2e.sh (10) — urgent completes in one cycle with 3 emails + a DigestSent object; newsletter suspends on the morning timer, then resumes to the same on "advancing the clock"; draft takes the else branch (no emails); a non-Article note is rejected by the guard; a duplicate activity fires once. flow:wait covered in next/flow (36/36). plans/fed-sx-design.md §13.10 documents the trigger fan-out as a kernel convention. lib/erlang 771/771. Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
flow-on-erlang — durable workflows in the fed-sx runtime
A native Erlang-on-SX port of the Scheme flow engine (lib/flow), so
the fed-sx kernel can fan arriving activities out into durable,
branching, multi-step business flows in its own runtime — no
cross-guest FFI, no marshalling, no Scheme dependency. The seed of a
real engine that can later supersede the Scheme one for substrate use.
Run the suite: bash next/flow/conformance.sh → engine conformance.
Model
A flow is an Erlang fun(Ctx) -> Ctx. Combinators (flow_spec)
compose flows; user code stays value-level (the functions you hand to
flow_node/branch/… take and return plain values). A flow that
ignores its input is a thunk; composition is function composition.
F = flow_spec:sequence([
flow_spec:flow_node(fun(Draft) -> Draft + 1 end),
flow_spec:branch(fun(P) -> P >= 3 end,
flow_spec:flow_const(ok),
flow_spec:flow_const(rejected))]),
flow:run(F, 2) %% => {flow_done, ok}
Durability — deterministic replay
Same semantics as the Scheme engine: a flow re-runs from the top on
every resume; effects/non-determinism go through flow:suspend/1,
whose resolved values are logged; an already-resolved suspend replays
its logged value, and the first unresolved suspend short-circuits back
to the driver. The persisted state is the replay log — plain
[{Tag, Value}] data — so nothing live (no continuation, no process)
is ever serialized; an instance survives restart by re-driving its
named flow against its log.
flow_store:register_flow(publish, F),
{ok, Id, R} = flow_store:start(publish, Draft), %% R = {flow_suspended, Tag} | {flow_done, V}
%% ... driver performs the effect for Tag, then:
flow_store:resume(Id, EffectResult) %% re-drives; completes or suspends again
Why railway threading instead of call/cc + a global
The Scheme engine uses an escape-only call/cc plus a mutable global
replay log. This Erlang-on-SX runtime can't do either, and has a third
sharp edge:
- No re-enterable continuation — but suspend only needs to escape,
which Erlang
throwcould do … - … except a blocking
receive/gen_server:callinside atrydeadlocks the cooperative scheduler. Sosuspendmust not consult the log via a registry process while inside atry. - No process dictionary — so there is no ambient per-process slot to stash the replay log in.
The resolution: thread the replay log through a railway-style context
and make suspend short-circuit (like a fail value) rather than
throw. No ambient state, no throw, no gen_server in the hot path —
purely functional, which sidesteps all three constraints. The driver
(flow_store) is the only stateful part, and it calls the pure
flow:drive/3 from inside handle_call, never wrapping a blocking
receive.
A Ctx is {flow_cont, Value, Log} (running) or {flow_susp, Tag, Log} (short-circuited); every combinator passes a suspended context
straight through.
Modules
| Module | Role |
|---|---|
flow.erl |
pure replay driver: drive/3, run/2, suspend/1, the Ctx constructors/accessors |
flow_spec.erl |
combinator algebra: leaves, sequence/parallel/map_flow, flow_while/flow_until, branch, railway fail/recover/attempt, tap, try_catch/retry |
flow_store.erl |
durable gen_server: named-flow registry + instance table + start/resume/status |
Consumed by
The fed-sx kernel's trigger fan-out (pipeline.erl + flow_dispatch)
starts named flows from arriving activities; see
plans/fed-sx-host-types.md and the triggers phases.
Not yet (later layers)
- Persisting instance logs to the kernel's durable on-disk log (the data shape is already restart-ready; only the backing is in-memory).
parallelwith multiple independent suspends resolving concurrently (currentparallelis sequential under one shared log).- Full parity with the Scheme engine's distributed/remote nodes.