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ywkang a796c1d2f7 ADR: bilingual structure — EN canonical in adr/, KO mirror in adr-ko/

Establish English as the canonical ADR language with Korean translations
held in a parallel docs/adr-ko/ tree as derived artifacts (1:1 mirror).
Promotion from adr-proposed/ to adr/ now writes English to adr/ and the
Korean to adr-ko/; bidirectional sync rule documented in CLAUDE.md.

- Migrate 30 ADRs in docs/adr/: 28 Korean-only translated to English,
  2 bilingual pairs (ADR-0020, ADR-0023) consolidated (.en.md suffix
  dropped). ADR-0023 EN regenerated against KO source which had newer
  HW Realization Notes (D16-D23) section.
- docs/adr-history/ left frozen by design (transitional state).
- CLAUDE.md (Part 2): update ADR Lifecycle for 4-folder layout, mark
  docs/adr-ko/ as a Derived Artifact, add ADR Translation Discipline
  section covering bidirectional sync, conflict resolution (EN wins),
  and proposed-language freedom.
- tools/verify_adr_lang_pairs.py: new verification tool checking pair
  completeness, filename mirroring, ADR-ID match, Status byte-equality.
  Pre-commit hook intentionally not added; run on demand or in CI.
- tests/test_verify_adr_lang_pairs.py: 11 cases including CRLF/LF
  normalization, em-dash title separator, underscore-slug edge case.

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

2026-05-20 01:38:44 -07:00

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ADR-0037: Forwarding Component (forwarding_v1)

Status

Accepted

Context

The simulation graph has many node positions that exist purely to model fabric traversal — NOC mesh routers, switches, UCIe protocol endpoints, IO chiplet io_noc, transit cubes. These share a common pattern: receive a message, apply per-component overhead (modeling header decode + routing decision time), forward to the next hop along the pre-computed path.

This ADR defines the contract for these transit nodes: a single component type (TransitComponent) that handles flit-aware forwarding with wormhole cut-through semantics, used under multiple impl names according to the conceptual role each instance plays.

Decision

D1. Role

The Forwarding component (TransitComponent class) is a stateless transit node in the simulation graph. It models any fabric position where a message physically traverses but no semantic processing happens.

Per traversal, the component:

Reads an incoming Transaction or Flit from an in_port.
Applies the configured per-component overhead (overhead_ns), applied once per Transaction even across multi-flit payloads (see D2).
Looks up the next hop along the Transaction's pre-computed path.
Forwards to the corresponding out_port; at the terminal node (no next hop), signals txn.done once the is_last flit arrives.

The component does NOT:

Decide routing — paths are pre-computed by the router (ADR-0002 / ADR-0017 D2). Forwarding only executes the per-hop step.
Model wire propagation or bandwidth occupancy — separate wire processes between components handle that (ADR-0015 D2).
Resolve addresses — the AddressResolver does that (ADR-0017 D9).
Aggregate completion — terminal endpoints (IO_CPU, M_CPU, HBM_CTRL) handle that.

D2. First-flit overhead model (header decode)

Per-Transaction overhead_ns is applied exactly once, at first flit arrival:

_txn_decoded: set[int] tracks which Transactions have already paid the overhead at this node.
On first-flit arrival for a Transaction: yield self.run(env, msg.txn.nbytes) — pays the overhead.
Subsequent flits of the same Transaction skip the overhead — they pipeline through with no extra delay.
On is_last flit: remove the Transaction from _txn_decoded.

This models the real-HW behavior where header decode and routing decision happen once on first flit; payload flits then stream through the same path (wormhole cut-through). Multi-hop pipelining emerges naturally — each hop adds its own first-flit overhead, but flits after the first do not re-pay overhead at any hop they have already passed first.

D3. Serial worker forwarding (preserves order)

The component's worker is a single SimPy process that consumes flits from _inbox and forwards them serially in arrival order. The component does NOT spawn env.process(...) per flit.

Rationale: if the first flit yields on overhead_ns while subsequent flits run in parallel processes, the later flits can overtake the first. This produces out-of-order delivery and lets the is_last flit arrive at the destination before the first flit — corrupting both the transaction's completion semantics and any flit-index-based processing downstream.

D4. Path-based next-hop routing

Routing is not a Forwarding-component concern. The Transaction arrives with a pre-computed path (built by the router; ADR-0002 / ADR-0017 D2). The component just looks up its own position in the path and forwards to path[index + 1]:

def _next_hop_in_path(self, txn):
    my_id = self.node.id
    path = txn.path
    for i, n in enumerate(path):
        if n == my_id and i + 1 < len(path):
            return path[i + 1]
    return None

If next_hop is found and present in out_ports, the flit is forwarded. Otherwise (terminal node), txn.done.succeed() is invoked when the is_last flit arrives.

D5. Flit-aware mode with Non-Flit fallback

_FLIT_AWARE = True opts this component out of the base class's flit-reassembly logic in _fan_in. Flits are placed directly on _inbox (no reassembly), enabling per-flit handling in the worker loop (D2, D3).

Non-Flit messages — zero-byte control Transactions and other non-chunkified payloads — fall through to the base class's legacy _forward_txn path via env.process. This preserves backward compatibility for control-plane traffic that does not benefit from flit-level processing.

D6. Multi-stream merging at the base class

Multi-stream FIFO merging at routers is the base class's responsibility, not Forwarding's. The base class's _fan_in spawns one process per in_port; all push to a single shared _inbox. Flits from different upstream streams therefore interleave at flit granularity in _inbox's FIFO order.

The Forwarding worker simply consumes _inbox in arrival order — correctly modeling per-router multi-flow arbitration as fair-FIFO over the shared inbox.

D7. Single implementation under multiple impl names

A single TransitComponent class is registered under four impl names in components.yaml:

builtin.forwarding — generic forwarding (e.g., io_noc, noc_router, UCIe conn bridges)
builtin.switch — tray-level switch
builtin.noc — cube-level NOC fabric (legacy singleton; current NOC routers use builtin.forwarding)
builtin.ucie — UCIe protocol endpoint

All four aliases instantiate the same class with the same behavior. Per-instance differentiation lives only in attrs.overhead_ns. Separate impl names exist as intent tags for readability and to allow future divergence without backward-incompatible config changes.

D8. Configurable `overhead_ns`

A single attribute drives per-instance latency:

Usage site	impl name	overhead_ns
Tray-level switch	`builtin.switch`	5.0
Cube NOC router	`builtin.forwarding`	2.0
IO chiplet io_noc	`builtin.forwarding`	0.0
UCIe protocol endpoint (`ucie-{N,S,E,W}`)	`builtin.ucie`	8.0
UCIe conn bridge (`ucie-{PORT}.conn{N}`)	`builtin.forwarding`	0.0

Default is 0.0. The attribute is read at each run() invocation, so dynamic reconfiguration is possible but not currently used.

Consequences

Positive

A single class handles all transit-node roles in the simulation graph — minimal code surface for a high-population component type.
Flit-aware processing + serial worker preserves wormhole semantics across multi-hop paths without per-flit process overhead.
overhead_ns is the only per-instance tunable; routing, BW, and address resolution stay cleanly separated in their own components / modules.
Multi-stream merging emerges from the base-class structure; no router-specific logic duplicates fair-FIFO arbitration.
Non-Flit fallback path keeps control-plane traffic working without forcing every message into the flit framework.

Negative

The single class hides usage-site intent inside attrs.overhead_ns configuration; readers must consult topology.yaml + components.yaml to see which impl name maps to which behavior class.
Per-flit serial worker is a bottleneck if overhead_ns is large and many concurrent transactions arrive at the same router; current values (0–8 ns) make this negligible.

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