0.2.0's AddZbSecretsAkkaReplication never bound its own ISecretReplicator: it
called AddZbSecrets first, which TryAdds NoOpSecretReplicator, so the package's
own TryAdd was silently discarded. Replication published into a no-op sink and no
actor was ever spawned - no exception, no log line. Found by the Task 6 wiring
work, which is the first code that ever built a container around that extension.
Fixed upstream in 0.2.1.
Test consequence worth recording: the replication-enabled registration tests
previously passed against a plain ActorSystem only BECAUSE of that bug - the
no-op never touched Akka. With 0.2.1 they resolve a real replicator, which spawns
the actor, whose PreStart needs DistributedPubSub and therefore a joined cluster,
so provider-based assertions hang. Standing a real cluster up inside this test
assembly was attempted and did not work, so these assertions are now made against
the ServiceCollection, which is precisely where the defect lives. Actor creation
and convergence remain covered upstream by the library's TwoNodeClusterReplication
tests against a genuine 2-node cluster.
7 registration tests pass in 23ms. Full solution builds 0 errors; no warnings
originate from these files.
Routes the host's secrets registration through a new AddOtOpcUaSecrets extension
that gates the ISecretStore implementation on Secrets:Replication:Enabled.
Opt-in gate (default FALSE)
This call decides which ISecretStore every node resolves — including driver-role
nodes with no auth/AdminUI, where a wrong store surfaces as drivers failing to
open sessions rather than as a failing test. With the flag false the wiring is
the pre-existing AddZbSecrets(config, "Secrets") call, unchanged, so current
behavior is byte-identical. With it true, AddZbSecretsAkkaReplication replaces
that call (it invokes AddZbSecrets internally; calling both would double-register).
Extracted to a named extension specifically so the registration is testable:
Program.cs is top-level statements and cannot be exercised by a container test,
which is how a "registered but never resolvable" defect ships unnoticed.
Serializer HOCON
AkkaSecretsReplication.SerializationConfig is merged into the ActorSystem config
inside the AddAkka configurator, conditionally on the same gate — a non-replicating
node carries no bindings for messages it will never see. Merged via
AddHocon(..., HoconAddMode.Append), Akka.Hosting's fallback merge and the same mode
the existing base-config merge uses; a raw Config.WithFallback would fight the
builder's own assembly.
Lazy-actor mitigation
The replication actor is created lazily on first ISecretStore resolution, so a node
that never touches a secret would never announce a manifest and would silently never
converge. SecretReplicationStarter (IHostedService) resolves the store once at
startup to make participation unconditional.
KNOWN BLOCKER — replication is currently NON-FUNCTIONAL; do not enable
ZB.MOM.WW.Secrets.Replicator.AkkaDotNet 0.2.0 never binds its own ISecretReplicator.
AddZbSecretsAkkaReplication calls AddZbSecrets FIRST, which does
TryAddSingleton<ISecretReplicator, NoOpSecretReplicator>(); the package's own
TryAddSingleton<ISecretReplicator>(AkkaSecretReplicator) that follows is therefore
a no-op. Verified empirically in a built container: with Enabled=true,
ISecretReplicator resolves to NoOpSecretReplicator, so ReplicatingSecretStore
publishes into a sink and no actor is ever spawned.
Consequence: the startup hook cannot create the actor, and the test asserting it
does is committed Skipped with the evidence. Not worked around here — the fix
belongs upstream (AddSingleton, or register before calling AddZbSecrets).
Because the flag defaults false, this commit is inert in production.
Tests: SecretsReplicationRegistrationTests (new) — disabled path resolves plain
SqliteSecretStore and needs no ActorSystem; enabled path resolves
ReplicatingSecretStore AND the undecorated concrete SqliteSecretStore the decorator
is built from (the exact registration gap that shipped once); startup hook registered
only when enabled. Red before wiring (4 assertion failures), green after: 6 pass,
1 skipped (blocker above).
Build: 861 warnings / 0 errors, unchanged from baseline (full --no-incremental A/B).
Host.IntegrationTests: 123 pass, 6 skip, 1 fail — AbCip_Green_AgainstSim, verified
pre-existing on the stashed tree (fixture-gated).
Claude-Session: https://claude.ai/code/session_01BL2Vu1ESDQ9SCN4gVKkdts
Version hygiene + picks up the G-8 KEK-rotation surface, and is the
precondition for adopting clustered secret replication. NOT a security fix
for this repo: SQLitePCLRaw.bundle_e_sqlite3 was already pinned to 2.1.12.
Post-implementation review (HIGH finding) noted #478's mux-delivered
input-quality path does not cover a driver comms-loss: a poll driver
(Modbus/S7) whose device goes unreachable emits only ConnectivityChanged and
goes silent on the value feed, so a scripted alarm keeps the last Good value.
The code as shipped faithfully implements #478's written scope (worst of input
tags' qualities via the dependency mux). The comms-loss bridge for scripted
alarms (symmetric of native #477-L2, plus the null-value/cold-start asymmetry
and its VT-quality ripple) is tracked as #481. Docs updated in
AlarmTracking.md + the design doc.
Layer 3 of #477: a scripted alarm's condition Quality now reflects the WORST
quality across its input tags, mirroring the native OT semantic (#477 L2).
Plumbing (quality was silently discarded twice on the live path):
- VirtualTagActor.DependencyValueChanged gains Quality (defaulted Good); the
DependencyMuxActor forwards the published AttributeValuePublished.Quality it
already carried; ScriptedAlarmHostActor.OnDependencyChanged pushes the real
quality into the engine (was hardcoded 0u/Good).
Engine (Core.ScriptedAlarms):
- ScriptedAlarmEngine computes worst-of-input quality each eval (skipping
not-yet-published inputs, which are a readiness concern, not a quality signal)
and carries it on ScriptedAlarmEvent.WorstInputStatusCode.
- A real transition carries the current worst quality so ToSnapshot's full
snapshot doesn't clobber quality back to Good (e.g. transition while Uncertain).
- A Bad input freezes the condition (no transition), like a comms-lost native
driver; a quality-bucket change with no transition emits the new
EmissionKind.QualityChanged, routed to the existing #477-L2
AlarmQualityUpdate -> WriteAlarmQuality node path (quality only, no /alerts
row, no historian write). ScriptedAlarmSource skips QualityChanged so it never
fabricates a phantom IAlarmSource event.
Host: ToSnapshot maps WorstInputStatusCode -> OpcUaQuality; OnEngineEmission
routes QualityChanged out of band.
Tests (TDD, RED-first): engine worst-carry + Bad/restore QualityChanged +
unchanged-bucket-no-emit; source swallows QualityChanged; mux forwards quality;
host Bad-dep -> AlarmQualityUpdate(no alerts) + transition snapshot carries worst.
Docs: AlarmTracking.md Layer-3 section + design doc.
Closes#478
Part 9 ConditionType.Quality was never assigned; default(StatusCode)==Good
so every native + scripted condition reported Good unconditionally — a
comms-lost device still showed a healthy, inactive, Good condition (a
wrong-VALUE bug, distinct from the null-value #473/#475). Clients (and HMIs
bucketing on IsGood) could not tell "genuinely inactive" from "lost contact".
Layer 1 — make Quality a real, plumbed field:
- AlarmConditionSnapshot gains OpcUaQuality Quality (default Good).
- MaterialiseAlarmCondition sets it (native BadWaitingForInitialData, scripted Good).
- WriteAlarmCondition projects snapshot.Quality; the delta-gate gains a Quality
member so a quality-bucket change fires a Part 9 event.
Layer 2 — drive native quality from driver connectivity (a comms-lost driver
emits no alarm transitions, and an alarm-bearing raw tag has no value variable,
so quality can't come from either existing channel):
- DriverInstanceActor Tells parent ConnectivityChanged on Connected/Reconnecting.
- DriverHostActor fans it to every native condition the driver owns as
OpcUaPublishActor.AlarmQualityUpdate (Good on connect, Bad on disconnect).
- New dedicated IOpcUaAddressSpaceSink.WriteAlarmQuality sets ONLY Quality and
fires only on a bucket change — never touches Active/Acked/Retain (an active
alarm that loses comms stays active). Not a full-snapshot re-projection, so it
can't clobber severity/message and works for a never-fired condition.
Forwarded through DeferredAddressSpaceSink (F10b trap; auto-verified by the
reflection forwarding guard). Ungated by redundancy role; no /alerts row.
Scripted conditions stay Good; worst-of-input quality deferred to #478 (Layer 3).
Tests: node-level (materialise/project/no-clobber/unknown-node no-op),
NativeAlarmProjector, DriverInstanceActor connectivity emission, DriverHostActor
fan-out, OpcUaPublishActor routing, and the wire-level guard
(Condition_event_Quality_tracks_source_connectivity_on_the_wire) — RED-verified
against a simulated pre-fix always-Good server. Existing DriverInstanceActor
parent probes ignore the new ConnectivityChanged.
Docs: docs/AlarmTracking.md §"Condition source-data Quality (#477)";
design doc docs/plans/2026-07-17-alarm-condition-quality-477-design.md.
MaterialiseAlarmCondition never assigned the mandatory Part 9 ConditionType
classification fields, so every condition event — native and scripted — shipped
ConditionClassId = NodeId.Null (i=0) and ConditionClassName = empty text. Same
mechanism as #473: Create() builds the mandatory children from the type's
embedded definition but leaves them unset, and nothing downstream synthesises
them (ReportEvent / InstanceStateSnapshot copy children verbatim). An HMI
bucketing alarms by condition class dropped every OtOpcUa alarm as unclassified.
Report BaseConditionClassType — Part 9's "no condition class modelled" value.
This is the honest report: we hold no classification at the materialise seam.
Deliberately NOT ProcessConditionClassType (the SDK sample's pick), which would
assert a classification we cannot back and would be actively wrong for a Galaxy
alarm whose upstream category is Safety/Diagnostics — trading a detectable null
for an undetectable lie. Real per-alarm classification needs the driver's
AlarmCategory carried to this deploy-time seam (it lives only on the runtime
AlarmEventArgs transition today) and is a separate feature.
Guards, both observed RED against the pre-fix server:
- NativeAlarmEventIdentityFieldDeliveryTests: wire-level, its own select clause
(the #473 test's clause mirrors ScadaBridge's exactly and its indices are
load-bearing, so it is left untouched). The class fields are declared on
ConditionType, not BaseEventType, so they are selected against that type.
- NodeManagerAlarmSourceFieldsTests: node-level, native (Raw) + scripted (Uns).
Stacked on #473 (PR #474) — merge after it.
MaterialiseAlarmCondition never assigned the three mandatory BaseEventType
identity fields, so all three arrived null on every condition event — native
and scripted. The SDK does not synthesise them on this path: Create() builds
the children from the type definition but leaves them unset, the auto-filling
BaseEventState.Initialize overload is only used for transient events, and
ReportEvent / InstanceStateSnapshot copy children verbatim. A conforming
client could not attribute an alarm to its source.
EventType = the concrete materialised type (TypeDefinitionId)
SourceNode = the condition's own NodeId (== ConditionId) — the condition IS
the source; an alarm-bearing raw tag materialises only the
condition, with no sibling value variable
SourceName = the same identifying id string: RawPath (native) /
ScriptedAlarmId (scripted)
SourceName carries the unique id rather than the leaf name: the leaf collides
across devices (HR200 on two PLCs) and is already carried by ConditionName, so
nothing is lost. Documented in docs/AlarmTracking.md, including that clients
must key on ConditionId and must not compose SourceName with ConditionName,
and that SourceName is NOT a live<->history join key (the alarm-history writer
stamps it with the EquipmentPath — a pre-existing divergence, now called out).
Tests: NativeAlarmEventIdentityFieldDeliveryTests is the wire-level guard —
a real client subscription using the standard [EventType, SourceNode,
SourceName, Time, Message, Severity] select clause, verified to fail against
the pre-fix server. NodeManagerAlarmSourceFieldsTests guards the node across
both realms, the base-type fallback, and the kind-swap re-materialise.
The HistoryRead events projection is a separate path (it projects historian
rows, not node fields) and is unaffected — its EventType => Variant.Null
assertions still hold.
The full-suite gate caught a real regression: AddOtOpcUaDriverFactories' registration
now resolves ISecretResolver (for Galaxy/OpcUaClient secret: refs, Tasks 7-8), so the
two ResilienceInvokerFactoryRegistrationTests that build a minimal container and resolve
the invoker factory threw 'No service for ISecretResolver'. The real host always
registers it via AddZbSecrets (unconditional, Task 3), and GetRequiredService correctly
fails-fast for a genuinely misconfigured host — so the fix is to complete the test
container with a stub resolver, matching production composition. Test-only.
Verify + regression-guard that the AdminUI driver-config editor persists secret:/
env:/file: refs verbatim and never resolve-then-resaves cleartext (which would
re-leak the secret into the config store, defeating G-2). Confirmed structurally
safe: DriverConfig is persisted as an opaque JSON string via RawTreeService, which
has NO secret-resolver dependency (only the DbContext factory) — resolution is
impossible on the save path. Resolution stays confined to driver-instantiation /
Test-connect (Tasks 7-8); GalaxyDriverBrowser resolves into a connect-scoped local
only, never writing back. Three round-trip tests (OpcUaClient Password/UserCertPassword,
Galaxy ApiKeySecretRef, env:/file: forms) exercise the real RawTreeService seam and
assert byte-identical save→reload. No product change (no leak found). 662 AdminUI tests pass.
Resolve secret:-prefixed Password + UserCertificatePassword through the shared
ISecretResolver, fail-closed on absent, retiring the cleartext-in-DB path. The
driver-registry factory is synchronous (Func<string,string,IDriver>), so resolution
is done lazily in the async session-open (InitializeAsync, before BuildUserIdentity)
rather than at deserialize — mirroring Task 7's Galaxy pattern and matching its
re-resolve-on-reconnect behavior. Both consumers (username Password and the
certificate-password LoadPkcs12 path via BuildCertificateIdentity) see the resolved
connect-scoped options; _options stays raw (secret: refs intact), no long-lived
plaintext field.
Scope corrections vs the plan (verified against v3): the probe is unauthenticated
GetEndpoints-only and never reads either credential, so it is NOT a resolution site
(comment added, no dead code); OpcUaClientDriverOptions was a sealed class, converted
to sealed record for the with-expression (no positional params → identical JSON; no
reference-equality/dict-key/ToString-log usages → no behavior/leak change).
ISecretResolver threaded via factory Register/CreateInstance + DriverFactoryBootstrap
(real resolver from DI); NullSecretResolver null-object backs test/parse paths only,
fail-closed on secret: refs. TDD: 4 helper tests RED→GREEN; 142 OpcUaClient tests pass.
Add a secret:NAME arm to GalaxySecretRef.ResolveApiKey that resolves the Galaxy
gateway API key through the shared ISecretResolver — fail-closed if the secret is
absent (never falls through to the cleartext literal arm), retiring the dev:/literal
in-DB path for production. Because GetAsync is async the method becomes
ResolveApiKeyAsync; the await cascade threads ISecretResolver by ctor injection into
GalaxyDriver + GalaxyDriverBrowser and (since GalaxyDriver is built by a static
factory closure, not DI) through GalaxyDriverFactoryExtensions + DriverFactoryBootstrap
(which pulls the real resolver from the service provider — registered unconditionally
in Slice 1). A NullSecretResolver null-object backs the parse-only/test paths only;
the runtime path always gets the real resolver (verified end-to-end).
TDD: 3 new secret:-arm tests (resolve / fail-closed-on-absent / no-literal-warning)
RED without the arm, GREEN with it; 338 Galaxy tests pass; no sync-over-async.
OtOpcUa is Akka-clustered and AddZbSecrets is registered unconditionally, so every
node (admin, driver, fused) resolves secrets and needs the SAME KEK + same store rows.
Ship G-5 as a production-posture runbook rather than hardcoding Source=File + shared
paths into the committed role-overlay appsettings (which dev + TwoNodeClusterHarness
also consume — that would break every dev/CI boot). Base appsettings stays on
Source=Environment. Documents the interim File-KEK + shared-SQLite posture and the
G-7 hand-off (ConfigDb-backed ISecretStore mirroring the existing DP
PersistKeysToDbContext<OtOpcUaConfigDbContext> key-ring sharing). Cross-linked from
docs/security.md. Mirrors the ScadaBridge G-5 resolution.
Mount the shared ZB.MOM.WW.Secrets.Ui RCL page at /admin/secrets on admin nodes:
- Register secrets:manage/secrets:reveal policies additively via
Configure<AuthorizationOptions>(o => o.AddSecretsAuthorization()) in AddAdminUI
(the admin-only composition layer that already references the RCL — avoids forcing
an RCL dependency into the core Security lib; mirrors HistorianGateway)
- Register the RCL routable assembly in BOTH the SSR endpoint (AddAdditionalAssemblies)
and the interactive Router (App.razor AdditionalAssemblies) or the route 404s
- Add a Secrets nav item; the page's own [Authorize(Policy=...)] gates access
Claim-type MATCH: AdminRole=Administrator reads the same ClaimTypes.Role as FleetAdmin,
so existing Administrators are authorized with no new role mapping. Full clean boot
verified; interactive reveal deferred to the live gate (shared UI already proven).
OtOpcUa commits no plaintext secrets — the only secret-shaped committed value is
ServerHistorian:ApiKey='' (empty, disabled by default). Because the pre-host expander
is fail-closed AND section-agnostic, hard-committing a ${secret:} token would break
every dev/CI/integration boot for zero at-rest benefit. Instead document the token
delivery convention for all five config secrets (jwt/ldap/deploy/configdb/historian)
in docs/security.md and note the token option in the ServerHistorian comments.
Mechanism proven live: unseeded token boot fails with SecretNotFoundException at
pre-host expansion; seeded token resolves and boot proceeds. Behavior-neutral
(comment + doc only).
Runtime ISecretResolver must be present on every clustered node regardless of
role: driver-only nodes resolve Layer-B DriverConfig secret: refs but have no
auth/DP/AdminUI (all admin-role-gated). Placed in the unconditional flow next to
AddOtOpcUaHealth(), outside both role blocks. Data Protection left untouched.
Adopt the ZB.MOM.WW.Secrets library (0.1.2, Gitea feed) into OtOpcUa under CPM:
- Directory.Packages.props + NuGet.config source mapping for the three packages
- Host/AdminUI/Driver.Galaxy.Contracts/Driver.OpcUaClient package references
- Layer-A pre-host ${secret:} config expander in Host/Program.cs, placed after all
config providers assemble and before the first config read (mechanism only,
behavior-neutral no-op until Task 4 introduces tokens)
- Secrets section in appsettings.json (env-var KEK, SQLite store, 30s cache TTL)
Mechanism mirrors the proven HistorianGateway adoption. KEK never committed.
M1 (MEDIUM): the VirtualTag re-assert re-published a stale last value with a
fresh deploy-time timestamp, and VirtualTagHostActor.OnResult recorded it to
the IHistoryWriter for Historize=true plans — every deploy would append an
artificial historian sample (BadInternalError if the last state was Bad) that
never corresponded to a real evaluation. Inert today (NullHistoryWriter) but a
data-quality bug once a VT history sink binds. Fix: EvaluationResult carries an
IsReassert flag (default false), set true in VirtualTagActor.OnReassertValue;
OnResult still PUBLISHES the AttributeValueUpdate (to repair the reset node) but
SKIPS _history.Record when IsReassert. Regression test
VirtualTagHostActorTests.Reassert_of_a_historized_vtag_publishes_but_does_not_re_record_to_the_historian
(fails before — count=2 — passes after: count stays 1).
LOW-3: corrected the ordering comments in VirtualTagActor.OnReassertValue and
VirtualTagHostActor.OnApply. ApplyVirtualTags goes to the VirtualTag HOST, not
the publish actor; the ordering holds because the re-assert reaches the publish
actor via a multi-hop chain (host -> child ReassertValue -> child -> parent
EvaluationResult -> OnResult -> publish actor) and thus lands AFTER
RebuildAddressSpace in the shared publish actor's FIFO mailbox.
M2 (CONFIRMED REAL — reported as scoped follow-up, not fixed here): the same
redeploy-reset race is latent for Part 9 scripted-alarm condition nodes. A
full-rebuild deploy clears + re-materialises them fresh
(OtOpcUaNodeManager.RebuildAddressSpace clears _alarmConditions @2160;
MaterialiseAlarmCondition recreates normal state), but the engine reload does
NOT re-emit an unchanged-active condition: ScriptedAlarmEngine.LoadAsync ->
EvaluatePredicateToStateAsync (@546-552) computes ApplyPredicate(seed, true)
where seed is the persisted state from the DB-backed EfAlarmConditionStateStore,
yielding EmissionKind.None, which ScriptedAlarmHostActor.OnEngineEmission (@292)
filters. Net: an active alarm with static dependencies under-reports until its
next real transition on a full-rebuild deploy. The fix is larger/riskier than
the VT case (touches the Core engine emission contract and must publish ONLY the
OPC UA node state, NOT the alerts topic, to avoid duplicate AVEVA history rows —
the alarm analogue of M1), so per review guidance it is deferred as a scoped
follow-up rather than forced into this commit.
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
Equipment VirtualTags published Bad at runtime whenever their dependency
value was static. Root cause: a deploy re-materialises each VirtualTag's
UNS node to BadWaitingForInitialData (OpcUaPublishActor.HandleRebuild), but
a surviving unchanged-plan VirtualTagActor keeps its value-dedup state, so
its unchanged recompute is suppressed (VirtualTagActor.OnDependencyChanged
value dedup) and the freshly-reset node stays Bad forever. Only masked when
the dependency value changes every poll.
Fix: VirtualTagHostActor tells each surviving (not just-spawned) child to
ReassertValue on every apply; the child re-emits its last value/quality,
bypassing dedup. Ordering is safe — DriverHostActor enqueues the
RebuildAddressSpace (materialise) to the single-threaded publish actor
before the ApplyVirtualTags that triggers the re-assert, so the re-publish
lands on the freshly-materialised node.
Regression test: VirtualTagHostActorTests
.Unchanged_redeploy_reasserts_last_value_so_a_reset_uns_node_recovers
(fails before, passes after). Live-verified on docker-dev: GateVt reads
Good via both the absolute and the {{equip}}/MainPressure script forms.
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
Pre-existing stale test surfaced by Batch 4's full gate (Batch 2/3 gates were
live-/run and never ran Host.IntegrationTests): Batch 2 registered CalculationProbe
in DriverFactoryBootstrap (9 probes) but AddOtOpcUaDriverProbes_is_idempotent's
AdminUiDriverTypeKeys still listed 8, so distinctTypes(9) != Length(8). Calculation
is a real DriverTypeNames.Calculation pseudo-driver with a probe; add it and refresh
the now-stale *DriverPage.razor comment (that routed flow retired in Batch 2). Not a
Batch-4 code change — a test-correctness fix.
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
M1 — over-the-wire event-delivery proof (new NativeAlarmMultiNotifierEventDeliveryTests
in OpcUaServer.IntegrationTests): boots the real server, wires one condition to two
equipment folders, fires ONE transition, and asserts a Server-object subscriber gets
EXACTLY ONE event (the shared-InstanceStateSnapshot queue dedup), plus overlapping
Server + equipment-folder subscribers each get exactly one copy. Captures via the
subscription FastEventCallback keyed by ClientHandle (the per-item Notification/DequeueEvents
path delivers nothing for these conditions in the SDK client — the working capture is the
fast callback).
M2 — resolution-failure signal + path-agreement tripwire (AddressSpaceApplier): when a
native alarm HAS ReferencingEquipmentPaths but NONE resolve to an equipment folder, count
it as a failed node (degraded-apply meter) + LogWarning instead of a silent skip; documented
the DisplayName==Name coupling as a binding invariant. Tests:
Composer_referencing_equipment_paths_resolve_back_to_equipment_ids_in_the_applier (real
composer output → applier inversion) + ..._unresolvable_referencing_equipment_counts_as_failed.
M3 — WireAlarmNotifiers is now a RECONCILE (unwires a folder dropped from the supplied set,
bidirectionally) so a future surgical ChangedRawTags path can't leave a de-referenced
equipment receiving the alarm; binding guard comment added on the classifier's
ChangedRawTags→Rebuild branch. Test: WireAlarmNotifiers_reconciles_a_dropped_folder_out_of_the_notifier_set.
L1 — MaterialiseAlarmCondition's kind-swap drop-and-recreate now calls
UnwireAlarmNotifiers(conditionKey) before discarding the old instance (teardown symmetry).
L3 — BuildEquipmentIdByFolderPath LogWarnings on a duplicate Area/Line/Name collision
(defense-in-depth; UNS uniqueness prevents it).
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
Closes the WP3/WP4 boundary seam WP4 flagged: ForwardNativeAlarm (DriverHostActor,
a WP3-owned file WP4 could not edit) built the AlarmTransitionEvent without the
referencing-equipment paths, so the /alerts equipment-list chips WP4 added never
populated in production (would fail live-gate leg 5). The RawTagPlan already carries
ReferencingEquipmentPaths (the Area/Line/Equipment UNS folder paths); this rides them
onto the per-condition alarm meta and into every transition. Coordinator-owned
1-file change (WP3 merged, no parallel agent owns this file this wave).
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
Materialize each native alarm ONCE at the raw tag (ConditionId = RawPath, Raw
realm); wire the single condition as an SDK event notifier of each referencing
equipment's UNS folder so one ReportEvent fans to every root without
re-reporting per root (which would break Server-object dedup + Part 9 ack
correlation).
- New sink method WireAlarmNotifiers(alarmNodeId, alarmRealm,
notifierFolderNodeIds, notifierFolderRealm) on IOpcUaAddressSpaceSink,
forwarded through DeferredAddressSpaceSink + SdkAddressSpaceSink +
NullOpcUaAddressSpaceSink (the forwarding-trap guard); auto-covered by the
DeferredSinkForwardingReflectionTests realm + forwarding guards + a
hand-written forward test.
- OtOpcUaNodeManager: the normative AddNotifier(isInverse) pair + idempotent
EnsureFolderIsEventNotifier per equipment folder; tracked per condition in
_alarmNotifierWiring. Teardown symmetry: RemoveNotifier(bidirectional:true) on
RebuildAddressSpace, RemoveAlarmConditionNode, and RemoveEquipmentSubtree so no
inverse-notifier entry leaks across redeploys.
- AddressSpaceApplier.MaterialiseRawSubtree wires notifiers for each native alarm
tag, resolving its ReferencingEquipmentPaths (Area/Line/Equipment) to the
EquipmentId folder NodeIds via BuildEquipmentIdByFolderPath.
- AlarmTransitionEvent gains ReferencingEquipmentPaths (empty default); /alerts
renders the referencing-equipment list as display metadata.
- Un-skipped + rewrote the native-alarm dark tests
(DriverHostActorNativeAlarmTests x6, DriverHostActorNativeAlarmAckRoutingTests
x1) for the v3 raw-condition model; new NodeManagerMultiNotifierAlarmTests
proves multi-notifier wiring + teardown symmetry (no leaked duplicates after a
re-trip) + applier wiring test.
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
H1 (HIGH): write-routing key now (AddressSpaceRealm, bareId), not bare-only.
A raw s=<RawPath> and a UNS s=<Area/Line/Equip/Eff> can collide as bare
strings; the bare-only key let a colliding raw+UNS pair route to the WRONG
driver ref (last-writer-wins). The realm the node manager resolves (RealmOf)
is now threaded through IOpcUaNodeWriteGateway.WriteAsync -> RouteNodeWrite ->
_driverRefByNodeId keyed by (realm, bareId). New regression test:
Colliding_raw_and_uns_bare_ids_route_to_their_own_driver_by_realm.
M1 (MEDIUM): discovered-node injection made coherently DORMANT. HandleDiscoveredNodes
hard-short-circuits (single enforcement point; _discoveredByDriver never
populates so the re-inject tail is inert too), with a clear log pointing at the
/raw browse-commit flow. New pin: Discovered_nodes_are_ignored_dormant_in_v3;
the 16+2 v2 injection scenarios re-pointed to an accurate skip reason
(DiscoveryInjectionDormantV3).
M2 (MEDIUM): realm-qualified dual-node self-correction tests —
Failed_uns_write_reverts_uns_node_and_leaves_raw_node_untouched +
Raw_realm_revert_reverts_raw_node_only (the second fails if the realm is dropped).
L1: removed the = AddressSpaceRealm.Uns defaults from the consequential
node-manager mutation methods (WriteValue/WriteAlarmCondition/MaterialiseAlarmCondition/
EnsureFolder/EnsureVariable/UpdateFolderDisplayName/UpdateTagAttributes/
RaiseNodesAddedModelChange/Remove*/RevertOptimisticWriteIfNeeded) + the
AttributeValueUpdate/AlarmStateUpdate records, so the compiler forces explicit
realm; read-only accessors + internal builders retain their defaults.
L3: fixed the stale VirtualTagHostActor class comment (V3NodeIds.Uns, not the
retired EquipmentNodeIds.Variable).
Also: DeploymentArtifactRawUnsParityTests — Raw/UNS node-set byte-parity
round-trip between AddressSpaceComposer.Compose and DeploymentArtifact.ParseComposition.
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
Wave B of Batch 4 — the runtime binding seam for the dual namespace.
Applier (both realms, explicit realm at every sink call site):
- MaterialiseRawSubtree: Raw containers as folders + Raw tags as variables
keyed by RawPath (native-alarm tag → single Part 9 condition at the RawPath),
all in AddressSpaceRealm.Raw; historian tagname = override else RawPath.
- MaterialiseUnsReferences: each UNS reference Variable under its equipment
folder (Uns realm) + an Organizes UNS->Raw edge; inherits writable/array/
historian tagname from the backing raw tag (both NodeIds -> one tagname).
- FeedHistorizedRefs / ProvisionHistorizedTags now source RAW tags (mux ref
stays single, keyed by RawPath); ApplyPureRemove tears down raw tags + UNS
refs in place (raw-container removal falls back to rebuild).
DriverHostActor (dual-NodeId, single-source fan-out):
- _nodeIdByDriverRef value gains a realm (NodeRealmRef); rebuilt from
RawTags UNION UnsReferenceVariables so one (DriverInstanceId, RawPath) fans
to the raw NodeId AND every referencing UNS NodeId with identical
value/quality/timestamp. Write inverse map keyed by the bare id; the
ns-qualified NodeId the write hook passes is normalised (BareNodeId) so a
write to either NodeId resolves the same driver ref (-> RawPath write).
- Native raw alarm condition routing is realm-tagged (Raw); AttributeValueUpdate
+ AlarmStateUpdate carry the realm through to the sink.
Retire EquipmentNodeIds -> V3NodeIds.Uns (applier/VirtualTagHostActor) and
RawPaths.Combine (DiscoveredNodeMapper, discovered nodes are Raw now).
DeploymentArtifact.ParseComposition emits the Raw + UNS subtrees byte-parity
with the composer (reconstruct entities -> AddressSpaceComposer.Compose).
Sink surface: removed the transitional `= AddressSpaceRealm.Uns` defaults from
IOpcUaAddressSpaceSink / ISurgicalAddressSpaceSink / SdkAddressSpaceSink /
DeferredAddressSpaceSink / NullOpcUaAddressSpaceSink — every call site is now
explicit (realm reordered before the trailing optionals on EnsureVariable +
MaterialiseAlarmCondition). Node-manager convenience methods keep their
defaults (they are not the interface impl; Sdk delegates explicitly).
Tests: rewrote DriverHostActorLiveValueTests (fan-out drift, 1:N) +
DriverHostActorWriteRoutingTests (dual-NodeId raw/uns write routing) to the v3
raw+uns model; new AddressSpaceApplierRawUnsTests; migrated the EquipmentTags
provisioning/feed tests to RawTags; swept EquipmentNodeIds test callers.
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
Close the Wave-A M1 gap: the sink surface had no way to wire the mandated
cross-tree Organizes reference from each UNS reference Variable to its backing
Raw node, forcing WP3 to reopen the frozen surface. Add a dedicated
realm-qualified AddReference method instead.
- IOpcUaAddressSpaceSink.AddReference(sourceNodeId, sourceRealm, targetNodeId,
targetRealm, referenceType="Organizes"): realm-qualified both ends; idempotent;
a missing endpoint is a logged no-op (never throws) so a mid-rebuild race can't
fault a deploy. Base-interface capability (no surgical sniff, no transitional
default — WP3 wires it explicitly per UNS reference variable).
- SdkAddressSpaceSink forwards to the node manager; DeferredAddressSpaceSink
forwards unconditionally (like EnsureFolder); NullOpcUaAddressSpaceSink no-ops.
- OtOpcUaNodeManager.AddReference: resolve both nodes by full ns-qualified key
(variable/folder/condition via ResolveNodeState), guard both-exist, then wire
the edge bidirectionally (forward Organizes on source, inverse on target) with a
ReferenceExists idempotency guard + ClearChangeMasks on mutated sides. Reference
type resolved by ResolveReferenceType (Organizes default). Added internal
GetNodeReferences test/diagnostic accessor.
- Reflection guard: the exhaustive-forwarding test + the realm-discriminator guard
auto-cover AddReference (it has two AddressSpaceRealm params) — no edit needed.
- New SdkAddressSpaceSinkTests: Organizes UNS→Raw edge created bidirectionally +
idempotent; missing endpoint is a safe no-op.
- All 15 IOpcUaAddressSpaceSink test doubles gain the AddReference no-op so the
solution still builds.
Build: dotnet build ZB.MOM.WW.OtOpcUa.slnx = 0 errors.
Tests: Commons.Tests 310/310; OpcUaServer.Tests 337 passed / 4 pre-existing skips.
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
Register both v3 namespaces (Raw first, UNS second) on OtOpcUaNodeManager and
thread an AddressSpaceRealm discriminator through every node-naming sink method
so a bare node id is resolved to the correct namespace by realm — never parsed
out of the id string.
- IOpcUaAddressSpaceSink / ISurgicalAddressSpaceSink: every node-naming method
gains `AddressSpaceRealm realm = AddressSpaceRealm.Uns` (transitional default so
un-migrated WP3 call sites still compile; WP3/Wave B makes them explicit and
removes the default). Null + SdkAddressSpaceSink impls updated; DeferredAddress-
SpaceSink forwards realm through every method (the forwarding trap).
- DeferredSinkForwardingReflectionTests: existing exhaustive-forwarding guard
auto-covers the new signatures; added an explicit guard that every node-naming
sink method carries an AddressSpaceRealm parameter (RebuildAddressSpace exempt).
- OtOpcUaNodeManager: register RawNamespaceUri + UnsNamespaceUri; realm->namespace
index via NamespaceIndexForRealm; all node maps (_variables/_folders/
_alarmConditions/_nativeAlarmNodeIds/_historizedTagnames/_eventNotifierSources)
re-keyed by the full ns-qualified NodeId string so Raw and UNS nodes sharing a
bare id stay distinct; _notifierFolders already NodeId-keyed. A historized UNS
reference node registers the SAME historian tagname as its backing raw node
(both NodeIds -> one tagname). Inbound-write hook routes the full ns-qualified
NodeId to the write gateway (realm-aware) and reverts by bare id + realm.
HistoryRead seams resolve via NodeId directly. DefaultNamespaceUri kept as a
transitional alias to UnsNamespaceUri for the SubscriptionSurvivalTests.
- Test doubles across Commons.Tests / OpcUaServer.Tests / Runtime.Tests updated to
the new interface signatures; SdkAddressSpaceSinkTests asserts the UNS namespace
index for default-realm nodes.
Build: dotnet build ZB.MOM.WW.OtOpcUa.slnx = 0 errors.
Tests: Commons.Tests 310/310; OpcUaServer.Tests 335 passed / 4 pre-existing skips.
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
Un-darken the address-space composition for the v3 dual namespace.
Composer (AddressSpaceComposer):
- Raw subtree: RawContainerNode (Folder/Driver/Device/TagGroup as
Object/Folder nodes, keyed s=<RawPath>, parent-before-child) + RawTagPlan
(raw tag Variables keyed (realm=Raw, s=<RawPath>) carrying DataType /
writable / historize+historian tagname / array shape). Native-alarm intent
attaches at the RAW tag (ConditionId = RawPath) with the list of referencing
equipment UNS paths (one alarm at the raw tag, not one per equipment).
- UNS subtree: UnsReferenceVariable per UnsTagReference, keyed
(realm=Uns, s=<Area>/<Line>/<Equipment>/<EffectiveName>), carrying its
backing RawPath (Organizes UNS->Raw target + fan-out) and inheriting
DataType/AccessLevel from the backing raw tag. Effective name =
DisplayNameOverride else backing raw Tag.Name.
- All RawPaths flow through one shared RawTopology (RawPathResolver +
memoised container paths), byte-parity with EquipmentReferenceMap.
- Every new node carries an AddressSpaceRealm (so WP3's applier picks the
namespace at the call site). Additive/defaulted model changes only — the
un-migrated AddressSpaceApplier still compiles.
Planner (AddressSpacePlanner.Compute) + AddressSpacePlan:
- Per-realm diff sets: RawContainers + RawTags keyed by RawPath (NodeId) so a
rename = remove+add; UnsReferenceVariables keyed by the stable
UnsTagReferenceId so a backing-tag rename re-points (BackingRawPath moves,
NodeId stable) and a display-name-override edit is UNS-only.
- PINNED: raw-tag rename = remove+add in Raw AND re-point in UNS.
Classifier folds the new sets in (adds->PureAdd, removes->PureRemove,
changed->Rebuild safe default).
Tests: AddressSpaceComposerDualNamespaceTests (7),
AddressSpacePlannerDualNamespaceTests (8, incl. the rename pin),
AddressSpaceChangeClassifierDualNamespaceTests (8); reactivated
EquipmentNamespaceMaterializationTests' Batch-4-pending case, re-authored to
drive the composer over the seeded config (the artifact-decode seam is WP3).
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
Batch 4 contracts commit (coordinator lands before Wave A fan-out). Purely
additive so wave agents branch from a green base:
- AddressSpaceRealm enum (Raw | Uns) — the explicit realm discriminator that
travels alongside a node's s= identifier at every sink seam (WP2 adds it to
IOpcUaAddressSpaceSink / ISurgicalAddressSpaceSink; WP3 threads it).
- V3NodeIds — the two namespace URI constants (https://zb.com/otopcua/raw,
https://zb.com/otopcua/uns, replacing the single .../ns) + Raw() pass-through
(s= id == RawPath) + Uns()/UnsChild() slash-joined Area/Line/Equipment[/Eff]
builders, both sharing RawPaths.Separator + ordinal segment validation.
Placement note: URIs live in V3NodeIds (Commons) rather than beside the retired
OtOpcUaNodeManager.DefaultNamespaceUri so runtime + tests reference them without
depending on OpcUaServer (single-source-of-truth, §5). WP2 rewires the node
manager to register both via V3NodeIds.RawNamespaceUri/UnsNamespaceUri.
EquipmentNodeIds retirement is NOT in this commit: its callers are the applier +
runtime (DriverHostActor/VirtualTagHostActor/DiscoveredNodeMapper), all WP3-owned
(the composer does not use it) — deleting it here would red the base. WP3 sweeps
it in Wave B.
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox
Uns.md Tags section rewritten to the reference-only model (UnsTagReference list,
cluster-scoped picker, effective-name uniqueness, {{equip}}/RefName); CLAUDE.md
gains a v3 Batch 3 paragraph. ScriptEditor.md was updated by WP4.
Claude-Session: https://claude.ai/code/session_01LVneM3eh1UtJxEisFXgmox