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T

Joseph Doherty a2dba4bd07 mbproxy: add in-flight read coalescing (Phase 10)

When two or more upstream clients send the same FC03/FC04 read while a
matching request is already in flight on the same PLC's multiplexed
backend socket, attach the late arrivals to the existing InFlightRequest
.InterestedParties list instead of opening a second backend round-trip.
The single backend response fans out to every attached party with each
party's original MBAP TxId restored individually. Zero post-response
staleness — coalescing operates entirely within the in-flight window
(microseconds to ~10 ms typical); the proxy is NOT a cache layer.

Headline mechanism:

- New record struct CoalescingKey(UnitId, Fc, StartAddress, Qty) keys
  the per-PLC InFlightByKeyMap. FC03 and FC04 are separate Modbus
  tables and never share a key; different unit IDs never coalesce;
  writes (FC06/FC16) bypass the coalescing path entirely.
- InFlightByKeyMap uses a simple lock around a Dictionary; atomic
  TryAttachOrCreate either appends a new party to the in-flight
  request's mutable List<InterestedParty> or invokes a factory to
  build a fresh entry. Per-entry MaxParties cap (default 32) bounds
  fan-out cost; past the cap, the next arrival opens a new entry.
- PlcMultiplexer.OnUpstreamFrameAsync takes the coalescing path for
  FC03/FC04 when Mbproxy.Resilience.ReadCoalescing.Enabled. The
  factory closure does the Phase-9 work (allocate TxId, add to
  CorrelationMap); the channel send happens AFTER returning from
  TryAttachOrCreate so the map lock is not held across the async send.
- Response fan-out in RunBackendReaderAsync removes the entry from
  InFlightByKeyMap before iterating InterestedParties, ensuring no
  concurrent attach can mutate the list during iteration.
- Cascade + watchdog paths also drain the key map so a stale entry
  cannot outlive its backend round-trip.

Counter accounting balance (per snapshot): CoalescedHitCount +
CoalescedMissCount equals total FC03 + FC04 requests since startup.
Even with coalescing disabled, every read still bumps Miss so dashboard
math stays balanced.

New surface (additive only):
- src/Mbproxy/Proxy/Multiplexing/CoalescingKey.cs
- src/Mbproxy/Proxy/Multiplexing/InFlightByKeyMap.cs
- src/Mbproxy/Proxy/Multiplexing/CoalescingLogEvents.cs
- ReadCoalescingOptions on ResilienceOptions
- CoalescedHitCount / CoalescedMissCount /
  CoalescedResponseToDeadUpstream counters surfaced on /status.json
  per PLC and as a compact "Coal" cell on the HTML status page.

Phase 9 test patch: TwoUpstreams_ProxyTxIds_AreDistinct_OnTheWire
previously read the same register from both clients (which now
coalesces). Patched to read two different addresses so the test still
proves distinct backend TxIds without violating the coalescing
contract.

Tests added: 24 new (19 unit + 5 E2E):
- CoalescingKeyTests (5)
- InFlightByKeyMapTests (6, includes concurrent stress)
- ReadCoalescingTests (8, stub-backend with deterministic delay)
- ReadCoalescingE2ETests (5, pymodbus simulator; coalescing-active
  during overlap is proven against the stub, not the sim, due to
  pymodbus 3.13's known concurrent-frame bug)

Total: 325 tests passing (282 unit + 43 E2E).

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

2026-05-14 02:26:06 -04:00

3.9 KiB

Raw Blame History

mbproxy

A .NET 10 Windows Service that sits inline as a Modbus TCP proxy in front of a fleet of AutomationDirect DirectLOGIC DL205/DL260 controllers, rewriting BCD-encoded registers bidirectionally so upstream clients can read and write them as plain integers.

Hard constraints / prerequisites

Windows 10 / Server 2019 or later, 64-bit. No Linux or Docker support — the service uses Microsoft.Extensions.Hosting.WindowsServices and the Windows Event Log.
Modbus TCP backends reachable from the proxy host on port 502 (or the port configured per PLC). The H2-ECOM100 module caps simultaneous connections at 4 per PLC — a fifth upstream client will fail to connect.
Admin rights to install the service (install.ps1 requires elevation).
No COM dependency — this is a pure .NET 10 socket-level proxy (unlike the .NET Framework 4.8 / x86 siblings in this repo).
Python 3.10+ on the test machine to run the pymodbus-backed E2E simulator (not needed to run the service in production).

Layout

src/Mbproxy/          Main C# project (net10.0, Microsoft.NET.Sdk.Worker)
tests/Mbproxy.Tests/  xUnit v3 test project (282 unit + 43 E2E tests)
install/              PowerShell install/uninstall scripts and config template
docs/                 Design document, phase plans, and operations runbook
DL260/                DL205/DL260 reference material and pymodbus simulator profile

Resource index

Task	Go to
Full architecture, schema, log events, status counters, test strategy	`docs/design.md`
Phase-by-phase implementation plan	`docs/plan/README.md`
Install, upgrade, config, logs, troubleshooting	`docs/operations.md`
DL205/DL260 Modbus quirks (BCD, CDAB, octal V-memory, FC limits)	`DL260/dl205.md`
pymodbus simulator profile (register seeds for E2E tests)	`DL260/dl205.json`
Agent-oriented coding guide (architecture bullets, device quirks, phase context)	`CLAUDE.md`

Build and run

Build (Debug, multi-file — fast for iteration):

dotnet build Mbproxy.slnx -c Debug

Publish (Release, single-file self-contained, win-x64):

dotnet publish src/Mbproxy/Mbproxy.csproj -c Release -r win-x64 --self-contained true -o C:\build\mbproxy-publish

The published output is a single Mbproxy.exe (~100 MB). The self-contained publish bundles the full .NET 10 + ASP.NET Core runtime. No .NET installation is required on the target machine.

Run tests:

dotnet test Mbproxy.slnx -c Debug                    # all tests
dotnet test Mbproxy.slnx -c Debug --filter Category=Unit   # unit tests only (no Python required)
dotnet test Mbproxy.slnx -c Debug --filter Category=E2E    # E2E tests (require Python + pymodbus)

Run interactively (without installing as a service):

cd src/Mbproxy
dotnet run --configuration Debug

Edit src/Mbproxy/appsettings.json to configure PLCs before running. The admin status page will be at http://localhost:8080/ by default.

Install

Full detail is in docs/operations.md. Quick path:

# 1. Publish
dotnet publish src/Mbproxy/Mbproxy.csproj -c Release -r win-x64 --self-contained true -o C:\build\mbproxy-publish

# 2. Install (elevated PowerShell)
.\install\install.ps1 -PublishOutput C:\build\mbproxy-publish -Start

# 3. Edit the config that was placed at %ProgramData%\mbproxy\appsettings.json

# 4. Verify
Invoke-WebRequest http://localhost:8080/ -UseBasicParsing

Maintenance

Documentation doctrine for this repo: ../DOCS-GUIDE.md.

This README routes to deep docs — it does not duplicate them.
Design decisions: docs/design.md is the source of truth.
When the service's public surface or task→tool mapping changes, update this README and the root ../CLAUDE.md index row.

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