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Joseph Doherty 4de222c950 Merge re/r1.4-gethi-finding: R1.1 ExecuteSqlCommand + R1.4 GetHistorianInfo (bounded)

# Conflicts:
#	docs/plans/hcal-roadmap.md
#	src/AVEVA.Historian.Client/HistorianClient.cs
#	src/AVEVA.Historian.Client/Protocol/Historian2020ProtocolDialect.cs
#	tests/AVEVA.Historian.Client.Tests/HistorianClientIntegrationTests.cs
#	tools/AVEVA.Historian.NativeTraceHarness/Program.cs

2026-06-21 16:18:49 -04:00

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HCAL modern-.NET client — implementation roadmap

Ordered, actionable plan to grow histsdk from "reads + basic config" into a broad HCAL replacement, built on the 2023 R2 gRPC transport. Derived from hcal-capability-matrix.md; event details in histevents.md.

Move to the repo's docs/plans/ when execution starts. Each work item lands as: a protocol serializer/parser + golden-byte unit test + an env-gated live integration test against the local Historian.

Progress (updated 2026-06-19)

✅ R0.6 version gate — HistorianServerVersionGate + HistorianClientOptions.VerifyServerInterfaceVersion; fail-closed on connect, wired into both WCF and gRPC paths. Supported versions are evidence-based (Hist=11, Retr=4, Trx=2; Status reachability-only), captured from the live server. 10 unit tests.
✅ CW-1 capture pipeline — ProtocolCaptureSanitizer + ProtocolFixtureWriter + capture-tag-info CLI command; produces sanitized fixtures/protocol/<op>/ golden files. 11 unit tests. First fixture: get-tag-info/analog-*.json.

⚠️ Live-verification constraint: the local Historian is 2020 (WCF, port 32568) — the 2023 R2 gRPC endpoint (32565) is absent. M0's gRPC routing (R0.1–R0.4) can be built and golden-byte/unit-tested here but cannot be live-verified without an actual 2023 R2 server. Treat gRPC ops as unverified until then; the byte payloads remain the proven 2020 protocol.

🔬 M1a re-classification (2026-06-20). Two "trivial" items were live-probed against the 2020 WCF server and found not deliverable here, both for evidence-backed reasons:

R1.3 GetServerTimeZoneAsync — Status.GetSystemTimeZoneName is a client-side stub on 2020 (rc=0, empty value), same family as GetServerTime. gRPC/2023R2-only.

R1.1 ExecuteSqlCommandAsync — ExeC returns native error 51 (InvalidParameter); the contract-3 string-handle ops require an unmapped native session/filter registration step (the StartTagQuery wall).

Takeaway: the M1a "cheap surface" is cheap only on the 2023 R2 gRPC front door. On 2020 WCF the boundary is the handle type (see the string-handle wall note under §1b and docs/reverse-engineering/wcf-string-handle-wall.md): uint-handle ops work, string-handle ops are blocked. GETHI/GetTepByNm were probed and confirmed blocked (not, as first guessed, reachable). The reachable uint-handle items are now DONE: ~~R1.8/R1.9 StartQuery summary/state modes~~ (resolved = existing ReadAggregateAsync) and ~~R1.7 event filters~~ (✅ 2026-06-20 — ReadEventsAsync(…, HistorianEventFilter), live-honored). M2 event send is also done (✅ WCF AddS2). R1.2 GetRuntimeParameterAsync is also done (✅ 2026-06-20, aa/Stat/GETRP, live-verified) — notably a string-handle op that punches through the wall using the Open2 storage-session GUID as an uppercase string handle, which proved the GETHI/ExeC failures were a handle-format issue rather than a missing native registration. Follow-up done: R1.1 ExecuteSqlCommandAsync shipped; R1.5 extended-property read shipped (R1.6 collapsed into it — no distinct localized op). R1.4 GetHistorianInfo bounded out on 2020 WCF — GETHI there is a named-value query (only HistorianVersion); EventStorageMode is 2023R2-gRPC-only (see wcf-historian-info.md). Net: the reachable 2020-WCF M1 read surface is complete; what remains is config writes (M1c — gated on an explicit user request) and the gRPC/2023R2-only items (R1.3 timezone, R1.4 EventStorageMode — need a live 2023 R2 server).

Guiding principles

gRPC-first. New ops go on the RemoteGrpc transport (clean protobuf envelope); the inner bytes blob is the only thing to RE. Keep WCF as the legacy/Windows path.
Two tests per op, always. A golden-byte test (deterministic, no server) and a gated live test (HISTORIAN_GRPC_HOST / HISTORIAN_HOST). No op is "done" without both.
Version-pin, fail closed. Read server version at connect; gate every byte serializer on it; throw ProtocolEvidenceMissingException on mismatch — never best-effort parse.
Capture once, encode forever. For CAPTURE-tier items, instrument one native call, save a sanitized fixture under fixtures/protocol/, then implement against the fixture.
Ship per milestone. Each milestone is independently releasable.

Effort: S ≈ days · M ≈ ~1 week · L ≈ weeks. Estimates are incremental on histsdk's existing infra (auth chain, transport, frame primitives, test harness).

Milestone 0 — Foundation: full gRPC parity for the DONE surface (M)

Goal: everything already working over WCF also works over RemoteGrpc, so the whole read/browse/status surface is Windows-free and the gRPC stack is the default path.

ID	Work	gRPC op	Files	Verify	Effort
R0.1	Route browse over gRPC	`Retrieval.StartTagQuery`/`QueryTag` or `GetTagInfosFromName`	`Grpc/HistorianGrpcReadOrchestrator` (+ new `…GrpcBrowseClient`), `Historian2020ProtocolDialect`	browse tags live over gRPC	S
R0.2	Route tag metadata over gRPC	`Retrieval.GetTagInfosFromName`	dialect + grpc client	metadata matches WCF result	S
R0.3	Route status/system-param over gRPC	`Status.GetSystemParameter`, `Status.GetHistorianConsoleStatus`	new `Grpc/HistorianGrpcStatusClient`	system param + conn status live	S
R0.4	Probe over gRPC	`*.GetInterfaceVersion`	grpc clients	`ProbeAsync` Windows-free	XS
R0.5	Capture harness for gRPC payloads	n/a	reuse `instrument-wcf-*` tooling (same byte blobs) + add a `grpc-call-dump` helper	dump any request/response `bytes` to a fixture	S
R0.6	Version gate	server version at connect	`HistorianClientOptions`, orchestrators	mismatched version → throws	S

Acceptance: the entire Phase-0 capability set runs end-to-end over RemoteGrpc (incl. Linux), no WCF on the path. 188+ unit tests green; live gRPC integration suite green.

Milestone 1 — Cheap surface completion (TRIVIAL/BOUNDED) (M–L total)

Goal: knock out the remaining read/config surface. Order = ascending payload difficulty.

1a. Trivial (XS–S each, no new payload format)

ID	Capability	gRPC op	Notes
~~R1.1~~	~~`ExecuteSqlCommandAsync`~~	`Retrieval.ExecuteSqlCommand` (`ExeC`+`GetR`)	✅ DONE (2026-06-20), live-verified. `ExecuteSqlCommandAsync(sql)` → `HistorianSqlResult` (columns + typed rows). String-handle op via the uppercase storage GUID. Chain: `Retr.GetV` prime → `ExeC(handle, sql, option=0, ref queryHandle)` → `GetR` loop (note: `GetR` returns false even on success — the stream is in `pResultBuff` regardless; false = final page). `GetR`'s `pResultBuff` is an NRBF-serialized `DataTable` (`SerializationFormat.Xml`: members `XmlSchema` + `XmlDiffGram`). BinaryFormatter is gone from .NET 10, so it's decoded read-only with `System.Formats.Nrbf` + `XDocument` (no BinaryFormatter). Shipped: `HistorianSqlResult`/`HistorianSqlColumn`/`HistorianSqlExecuteOption`, `HistorianSqlResultProtocol`, `HistorianWcfSqlClient`, golden `WcfSqlResultProtocolTests`, gated live tests. See `docs/reverse-engineering/wcf-exec-sql.md`.
~~R1.2~~	~~`GetRuntimeParameterAsync`~~	`Status.GetRuntimeParameter` (`aa/Stat/GETRP`)	✅ DONE (2026-06-20), live-verified. Captured (`scripts/Capture-RuntimeParam.ps1`): GETRP is a `string`-handle op (GETHI's shape), but reachable from the managed client using the Open2 storage-session GUID as an uppercase string handle (`ToString("D").ToUpperInvariant()`). Returns `HistorianVersion` = `20,0,000,000` live. pRequestBuff = `54 67 01 00` + uint nameCount + per-name(uint charCount + UTF-16); pResponseBuff = version + uint resultCount + CRetVariant(`0x43` VT_BSTR + uint16 len + uint16 charCount + UTF-16). Single string-valued param only (multi-name framing inferred, not captured). Shipped: `HistorianClient.GetRuntimeParameterAsync(name)`; golden `WcfRuntimeParameterProtocolTests`. Note: GETRP punching through the string-handle wall with the uppercase storage GUID is a strong lead that GETHI/ExeC may be a handle-format issue — see `wcf-string-handle-wall.md` §Update.
~~R1.3~~	~~`GetServerTimeZoneAsync`~~	`Status.GetSystemTimeZoneName`	⛔ gRPC/2023R2-only — re-confirmed 2026-06-21 from 3 angles. (1) native `GetSystemTimeZoneName` is a stub (rc=0, empty) in the `GetServerTime` family; (2) Runtime DB has no timezone `SystemParameter` — the zone exists only as per-block `HistoryBlock.TimeZoneOffset`/`wwTimeZone` (DST-specific, SQL-only) + a `TimeZone` lookup table, `StorageShard.TimeZoneId`=NULL; (3) `GetSystemParameter` + `GETRP` return null/throw for every timezone candidate (only `HistorianVersion` works). The sole 2020 route is a SQL read via `ExecuteSqlCommand` (R1.1) — DST-specific, different mechanism. Build the real op only against a live 2023 R2 server. See `docs/reverse-engineering/wcf-status-localhost.md`.

✅ String-handle "wall" RESOLVED (2026-06-20) — it was a handle-FORMAT bug. R1.4/R1.5/R1.6 (and R1.1) take a string GUID handle; the earlier "code 1/51 blocked" verdict came from passing the Open2 storage GUID in .NET's default lowercase. Sent uppercase (storageSessionId.ToString("D").ToUpperInvariant()) the same handle works: GETRP (R1.2, shipped), GETHI (R1.4) and ExeC (R1.1) are all live-verified reachable, and R1.5 GetTepByNm is now shipped + live-verified (GetTagExtendedPropertiesAsync). R1.6 has no distinct op (collapses into R1.5). Note: QTB (StartTagQuery) does not punch through — it fails server-side (CMdServer::StartActiveTagnamesQuery over the aahMetadataServer pipe), independent of handle format, so the index-based property/query paths stay blocked here. Full analysis: docs/reverse-engineering/wcf-string-handle-wall.md (RESOLVED banner) and docs/reverse-engineering/wcf-tag-extended-properties.md. R1.8/R1.9 (StartQuery summary/state modes) are uint-handle and were already reachable.

1b. Bounded (decode one `bytes` payload; S–M each)

ID	Capability	gRPC op	Payload to decode	Depends
~~R1.4~~	`GetHistorianInfoAsync`	`Status.GetHistorianInfo` (`GETHI`)	⛔ BOUNDED OUT on 2020 (re-confirmed 2026-06-21). GETHI is a named-value query reachable via the uppercase storage GUID, but only `HistorianVersion` resolves — the full 518-byte `HISTORIAN_INFO` struct (incl. `EventStorageMode`@514) is the 2023R2 HCAL-native/gRPC model. `EventStorageMode` has no 2020 representation at all: not a `SystemParameter` (only `EventStorageDuration`/`EventStorageLogPath`), not a DB column, and `GETRP`/`GetSystemParameter` return null/throw for it. The only 2020-reachable field (version) is already shipped via `GetSystemParameterAsync`/`GetRuntimeParameterAsync`, so a struct API would be hollow + misleading. Build the real op only against a live 2023 R2 server. See `docs/reverse-engineering/wcf-status-localhost.md`.	uppercase string handle
~~R1.5~~	Extended-property read	`Retrieval.GetTagExtendedPropertiesFromName` (`GetTepByNm`)	✅ DONE (2026-06-20), live-verified. `GetTagExtendedPropertiesAsync(tag)` → name/value pairs. String-handle op via the uppercase storage GUID; name-based path (`GetTagExtendedPropertiesByName`, not the QTB-gated TagQuery path). Request `tagNames` = `uint count` + per-name(`uint charCount`+UTF-16); response = `uint tagCount` + per-tag(marker + compact-ASCII name + `uint propCount` + per-prop(marker + compact-ASCII name + `0x43` VT_BSTR value) + trailer). Sequence-paged. Shipped: `HistorianTagExtendedPropertyProtocol`, golden `WcfTagExtendedPropertyProtocolTests`, gated live test. See `docs/reverse-engineering/wcf-tag-extended-properties.md`.	uppercase string handle
~~R1.6~~	Localized-property read	(no op)	⛔ No distinct op on 2020 — collapses into R1.5. There is no `GetTagLocalizedPropertiesFromName`/`GetTlpByNm` or `GetTagLocalizedPropertiesByName` in `current/aahClientManaged.dll`; the only "localized" surfaces are error-message/UI-text localization. Extended properties (R1.5) are the user-defined tag-property read surface. Closed, not throwing.	—
~~R1.7~~	Event filters	filter bytes in `Retrieval.StartEventQuery`	✅ DONE (2026-06-20), live-honored. `ReadEventsAsync(start, end, HistorianEventFilter)`. The filter rides `StartEventQuery`'s `pRequestBuff` (captured via `EventQuery.AddEventFilter` + instrument-wcf-writemessage; Equal vs Contains diffed to isolate the op). Filter block: `ushort 0 + uint filterCount + uint condCount + uint nameLen + name(UTF-16) + uint 1 + ushort op + uint 1 + value(0x09-len-0x00 compact-ASCII) + byte 0`. REAL, not inert (a non-matching predicate returns 0 events; matching returns the subset). Single string-valued predicate only; multi-filter (OR) / multi-condition (AND via `AddEventFilterCondition`) framing not yet fully captured. See `HistorianEventFilter`, golden `WcfEventQueryProtocolTests`.	—
R1.8	Analog-summary query	`Retrieval.StartQuery` (summary mode)	summary row layout — `uint`-handle, reachable. Scoped + decode targets located (`CAnalogSummaryValue.UnpackFromValueBuffer`, fields Min/Max/First/Last/ValueCount/Integral/…). Plan: `r1.8-r1.9-summary-queries.md`	—
R1.9	State-summary query	`Retrieval.StartQuery` (state mode)	state-summary row layout — `uint`-handle, reachable. Scoped (`CStateSummaryStruct`: MinContained/MaxContained/TotalContained/PartialStart/PartialEnd/StateEntryCount). Plan: `r1.8-r1.9-summary-queries.md`	—

1c. Bounded config writes (S–M each)

ID	Capability	gRPC op	Payload	Notes
R1.10	`RenameTagsAsync`	History rename op	rename request buffer	`AllowRenameTags` already probed
~~R1.11~~	Extended-property write	`History.AddTagExtendedProperties` (AddTEx)	✅ Add DONE (2026-06-21), live-verified. `AddTagExtendedPropertiesAsync`/`AddTagExtendedPropertyAsync` (write mode, uppercase handle). inBuff = exact inverse of the R1.5 read framing (`uint32 groupCount + 0x01 + compact-ASCII tag + uint32 propCount + per prop[0x02 + compact-ASCII name + 0x43 VT_BSTR value] + 0x01 trailer + 0x00 terminator`); the trailing `0x00` is required or the server throws. Golden `WcfTagExtendedPropertyWriteProtocolTests` + gated live write/read-back test. Delete (DelTep): wire format CAPTURED + serializer golden-proven (2026-06-21), but live delete is server-blocked and NOT shipped. Captured via a two-session trick (add in Run A → fresh-session read-sync → delete in Run B, past the native err-229 client gate); inBuff = same group framing as Add but property-name-only and a `0x00` group trailer. A decisive experiment shows SDK-added properties ARE deletable (the native client deletes one), so SDK-add is complete; the SDK's own DelTep is rejected (`SErrorException` in `CHistStorage::DeleteTagExtendedProperties`) despite matching mode/handle/inBuff + GetTgByNm/GetTepByNm prime + open channel + 60s retries. Root cause: the native multiplexes services over ONE connection (per-connection working set), which the SDK's per-service WCF channels don't reproduce — needs transport-level multiplexing. See `docs/reverse-engineering/wcf-add-tag-extended-properties.md` §Delete.
~~R1.12~~	Localized-property write	(no op)	⛔ No distinct op on 2020 — closed (mirror of R1.6). A symbol sweep of `current/.dll` finds no `AddTagLocalizedProperties` / `DeleteTagLocalizedProperties` / any `LocalizedPropert` / `TagLocalized`; only UI/error-text localization (`GetLocalizedText`/`GetLocalizedMessage`/`LocalizedResourcesDir`). Localized properties are a 2023 R2/gRPC concept. Closed, not throwing. See `docs/reverse-engineering/wcf-tag-extended-properties.md` §R1.12.	2026-06-21
~~R1.13~~	Non-analog tag create (string/discrete)	`History.EnsureTags`	distinct CTagMetadata variant	⛔ GATED — bounded out (2026-06-21, live-probed). Native `AddTag` rejects every non-analog type client-side (`ErrorCode=ValidationFailed` / "Transaction validation failed", before any WCF op): SingleByteString, DoubleByteString, and Int1 all fail; Float (control) succeeds. The native `HistorianDataType` enum has no Discrete/Boolean and no Int8/UInt8 (SDK-only extensions); `HistorianTag` has no TagType setter (type is data-type-derived). So no non-analog wire request is ever emitted → nothing to capture/implement. String/discrete create goes via a different subsystem (config editor / SQL), not this client's AddTag. `EnsureTagAsync` stays analog-only. See `docs/reverse-engineering/wcf-non-analog-tag-create.md`.

Acceptance: read + browse + metadata + system/status + property R/W + summaries + event-filtered reads + rename all live-verified over gRPC.

Milestone 2 — Event sending (CAPTURE) (S–M) ← headline gap

Goal: SendEventAsync(HistorianEvent). Path fully mapped in histevents.md; one capture away.

✅ DONE (2026-06-20) — HistorianClient.SendEventAsync(HistorianEvent) shipped and live-accepted over 2020 WCF. The headline assumption — that event delivery would ride the non-WCF storage-engine pipe (and so be blocked like revision writes) — was disproved by capture: a native AddStreamedValue(HistorianEvent) leaves over WCF as AddS2 (IHistoryServiceContract2.AddStreamValues2). CM_EVENT is a built-in registered tag, so the 129 TagNotFoundInCache gate that blocks AddS2 for user tags does not apply to events. The full managed chain (Open2 event-mode 0x501 → CM_EVENT RTag2/EnsT2 → AddS2) is accepted by the server (AddS2 returns success, empty error buffer). See the event-send field map under §"Event-send wire format" in histevents.md and HistorianEventWriteProtocol.

⚠️ Persistence caveat (environment, not SDK): on the local dev Historian, accepted events are not persisted to the queryable store (v_AlarmEventHistory2 latest stays at the pre-test date; count only ages down). The native client exhibits the identical behaviour (its AddS2 also returns success but nothing lands), so this is the box's event-ingestion pipeline not being active — not an SDK protocol gap. The SDK emits byte-equivalent AddS2 (golden-tested). Full send→store→read-back round-trip awaits a Historian with an active event storage pipeline.

ID	Work	Status
R2.1	Capture the event value blob	✅ `scripts/Capture-EventSend.ps1` (event-send harness scenario + instrument-wcf-{write,read}message); two captures diffed to separate constant framing from value fields. Decisive finding: event-send = WCF `AddS2`, not storage pipe.
R2.2	`HistorianEventWriteProtocol`	✅ Serializes the `AddS2` pBuf (storage sample buffer wrapping the event VTQ): "OS" sig + sampleCount + length fields + CM_EVENT tag id + EventTime FILETIME + OpcQuality + opaque descriptor + event Id + ReceivedTime FILETIME + Namespace + EventType + version + typed property bag (string props reuse the read parser's `0x43` encoding). Golden-byte test pins capture A.
R2.3	Event write orchestrator	✅ `HistorianWcfEventOrchestrator.SendEventAsync`: Open2 (0x501) → reuse CM_EVENT RTag2/EnsT2 registration → `AddStreamValues2(handle, pBuf, out err)` on the same /Hist channel + storage-session handle.
R2.4	Public API	✅ `HistorianClient.SendEventAsync(HistorianEvent)`. Original events only (RevisionVersion=0) with string-valued properties; other property types + revision/update/delete throw `ProtocolEvidenceMissingException` until captured.
R2.5	Round-trip test	✅ Golden-byte on R2.2 + gated live test `SendEventAsync_AgainstLocalHistorian_AcceptedByServer` (asserts server acceptance; SQL read-back best-effort given the persistence caveat).

Acceptance: an event sent from histsdk is accepted by the historian over WCF with a byte-correct AddS2 (✅). Appears-and-reads-back is environment-gated on event persistence (see caveat).

Milestone 3 — Historical / non-streamed value writes (BOUNDED) (M)

Goal: insert original historical VTQs (backfill), the path that is NOT the gated cache push.

ID	Work	gRPC op
R3.1	Decode non-streamed VTQ packet	`Transaction.AddNonStreamValuesBegin/AddNonStreamValues/End`
R3.2	`AddHistoricalValuesAsync`	batched begin→values→end
R3.3	Ingest-permission validation	confirm the target accepts original-data insert (distinct from `AddS2` cache wall)

Acceptance: historical points inserted and read back. Document clearly where this differs from (gated) streaming sample writes.

Milestone 4 — HARD subsystems (deferred / optional) (L each)

Only if the use case demands them. Each is a real subsystem, not an op.

ID	Capability	Approach	Risk
R4.1	Store-and-forward	Pragmatic local queue (durable outbox + replay on reconnect) rather than bit-faithful SF cache + `Forward*Snapshot`. Faithful SF = decode SF cache format + snapshot framing + recovery log	high; consider "good enough"
R4.2	Revision / edit writes	`AddRevisionValue(s)` go via the non-WCF storage-engine pipe (`STransactPipeClient2`) — separate transport RE	high
R4.3	Real store-forward status	duplex push (`SetStoreForwardEvent`) or a decoded pull endpoint — see store-forward plan	medium
R4.4	Multi-historian / redundancy	client-side orchestration over N single-historian sessions (failover, ReSyncTags, partner watchdog) — build last	medium

Won't-do from the client (GATED)

Streaming process-sample writes (AddStreamedValue(HistorianDataValue) / AddS2): runtime cache only ingests from configured IOServer/AppServer pipelines. Confirm your ingestion architecture instead of pursuing this.

Cross-cutting workstreams (run alongside all milestones)

CW-1 Capture tooling (enables R0.5, R1.x, R2.1): one reusable "call op → dump request/response bytes → sanitized fixture" path. Highest leverage — do first.
CW-2 Version compatibility: matrix of tested Historian versions; serializers keyed by version; CI gate.
CW-3 Cross-platform CI: run the gRPC suite on Linux/macOS (transport is portable; explicit-cred auth path).
CW-4 Fixtures discipline: every new op ships a fixtures/protocol/<op>/ golden file; sanitize hostnames/tags/GUIDs before commit.
CW-5 Public API shape: keep the modern surface (async, IAsyncEnumerable, cancellation, options record, DI-friendly) consistent as the surface grows.

Sequencing (critical path)

CW-1 capture tooling ─┐
M0 gRPC parity ───────┼─→ M1 cheap surface ─→ M2 event send ─→ M3 historical writes ─→ (M4 optional)
R0.6 version gate ────┘

Recommended first sprint: CW-1 + M0 (R0.1–R0.6) → a fully Windows-free, version-safe gRPC client at today's capability. Second sprint: M1a + M2 (cheap wins + the headline event-send). M3/M4 as demand dictates.

One-glance status

Milestone	Tier	Effort	Value	When
M0 gRPC parity + capture tooling	foundation	M	unblocks everything, Windows-free	now
M1 cheap surface	TRIVIAL/BOUNDED	M–L	most remaining read/config	next
M2 event send	CAPTURE	S–M	headline write capability	next
M3 historical writes	BOUNDED	M	backfill	on demand
M4 SF / revisions / redundancy	HARD	L×N	parity completeness	defer

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