朱子纯 / vibe-erp

New platform subproject `platform/platform-workflow` that makes
`org.vibeerp.api.v1.workflow.TaskHandler` a live extension point. This
is the framework's first chunk of Phase 2 (embedded workflow engine)
and the dependency other work has been waiting on — pbc-production
routings/operations, the full buy-make-sell BPMN scenario in the
reference plug-in, and ultimately the BPMN designer web UI all hang
off this seam.

## The shape

- `flowable-spring-boot-starter-process:7.0.1` pulled in behind a
  single new module. Every other module in the framework still sees
  only the api.v1 TaskHandler + WorkflowTask + TaskContext surface —
  guardrail #10 stays honest, no Flowable type leaks to plug-ins or
  PBCs.
- `TaskHandlerRegistry` is the host-side index of every registered
  handler, keyed by `TaskHandler.key()`. Auto-populated from every
  Spring bean implementing TaskHandler via constructor injection of
  `List<TaskHandler>`; duplicate keys fail fast at registration time.
  `register` / `unregister` exposed for a future plug-in lifecycle
  integration.
- `DispatchingJavaDelegate` is a single Spring-managed JavaDelegate
  named `taskDispatcher`. Every BPMN service task in the framework
  references it via `flowable:delegateExpression="${taskDispatcher}"`.
  The dispatcher reads `execution.currentActivityId` as the task key
  (BPMN `id` attribute = TaskHandler key — no extension elements, no
  field injection, no second source of truth) and routes to the
  matching registered handler. A defensive copy of the execution
  variables is passed to the handler so it cannot mutate Flowable's
  internal map.
- `DelegateTaskContext` adapts Flowable's `DelegateExecution` to the
  api.v1 `TaskContext` — the variable `set(name, value)` call
  forwards through Flowable's variable scope (persisted in the same
  transaction as the surrounding service task execution) and null
  values remove the variable. Principal + locale are documented
  placeholders for now (a workflow-engine `Principal.System`),
  waiting on the propagation chunk that plumbs the initiating user
  through `runtimeService.startProcessInstanceByKey(...)`.
- `WorkflowService` is a thin facade over Flowable's `RuntimeService`
  + `RepositoryService` exposing exactly the four operations the
  controller needs: start, list active, inspect variables, list
  definitions. Everything richer (signals, timers, sub-processes,
  user-task completion, history queries) lands on this seam in later
  chunks.
- `WorkflowController` at `/api/v1/workflow/**`:
  * `POST /process-instances`                       (permission `workflow.process.start`)
  * `GET  /process-instances`                       (`workflow.process.read`)
  * `GET  /process-instances/{id}/variables`        (`workflow.process.read`)
  * `GET  /definitions`                             (`workflow.definition.read`)
  * `GET  /handlers`                                (`workflow.definition.read`)
  Exception handlers map `NoSuchElementException` +
  `FlowableObjectNotFoundException` → 404, `IllegalArgumentException`
  → 400, and any other `FlowableException` → 400. Permissions are
  declared in a new `META-INF/vibe-erp/metadata/workflow.yml` loaded
  by the core MetadataLoader so they show up under
  `GET /api/v1/_meta/metadata` alongside every other permission.

## The executable self-test

- `vibeerp-ping.bpmn20.xml` ships in `processes/` on the module
  classpath and Flowable's starter auto-deploys it at boot.
  Structure: `start` → serviceTask id=`vibeerp.workflow.ping`
  (delegateExpression=`${taskDispatcher}`) → `end`. Process
  definitionKey is `vibeerp-workflow-ping` (distinct from the
  serviceTask id because BPMN 2.0 ids must be unique per document).
- `PingTaskHandler` is a real shipped bean, not test code: its
  `execute` writes `pong=true`, `pongAt=<Instant.now()>`, and
  `correlationId=<ctx.correlationId()>` to the process variables.
  Operators and AI agents get a trivial "is the workflow engine
  alive?" probe out of the box.

Why the demo lives in src/main, not src/test: Flowable's auto-deployer
reads from the host classpath at boot, so if either half lived under
src/test the smoke test wouldn't be reproducible from the shipped
image — exactly what CLAUDE.md's "reference plug-in is the executable
acceptance test" discipline is trying to prevent.

## The Flowable + Liquibase trap

**Learned the hard way during the smoke test.** Adding
`flowable-spring-boot-starter-process` immediately broke boot with
`Schema-validation: missing table [catalog__item]`. Liquibase was
silently not running. Root cause: Flowable 7.x registers a Spring
Boot `EnvironmentPostProcessor` called
`FlowableLiquibaseEnvironmentPostProcessor` that, unless the user has
already set an explicit value, forces
`spring.liquibase.enabled=false` with a WARN log line that reads
"Flowable pulls in Liquibase but does not use the Spring Boot
configuration for it". Our master.xml then never executes and JPA
validation fails against the empty schema. Fix is a single line in
`distribution/src/main/resources/application.yaml` —
`spring.liquibase.enabled: true` — with a comment explaining why it
must stay there for anyone who touches config next.

Flowable's own ACT_* tables and vibe_erp's `catalog__*`, `pbc.*__*`,
etc. tables coexist happily in the same public schema — 39 ACT_*
tables alongside 45 vibe_erp tables on the smoke-tested DB. Flowable
manages its own schema via its internal MyBatis DDL, Liquibase manages
ours, they don't touch each other.

## Smoke-test transcript (fresh DB, dev profile)

```
docker compose down -v && docker compose up -d db
./gradlew :distribution:bootRun &
# ... Flowable creates ACT_* tables, Liquibase creates vibe_erp tables,
#     MetadataLoader loads workflow.yml, TaskHandlerRegistry boots with 1 handler,
#     BPMN auto-deployed from classpath
POST /api/v1/auth/login → JWT
GET  /api/v1/workflow/definitions → 1 definition (vibeerp-workflow-ping)
GET  /api/v1/workflow/handlers → {"count":1,"keys":["vibeerp.workflow.ping"]}
POST /api/v1/workflow/process-instances
     {"processDefinitionKey":"vibeerp-workflow-ping",
      "businessKey":"smoke-1",
      "variables":{"greeting":"ni hao"}}
  → 201 {"processInstanceId":"...","ended":true,
         "variables":{"pong":true,"pongAt":"2026-04-09T...",
                      "correlationId":"...","greeting":"ni hao"}}
POST /api/v1/workflow/process-instances {"processDefinitionKey":"does-not-exist"}
  → 404 {"message":"No process definition found for key 'does-not-exist'"}
GET  /api/v1/catalog/uoms → still returns the 15 seeded UoMs (sanity)
```

## Tests

- 15 new unit tests in `platform-workflow/src/test`:
  * `TaskHandlerRegistryTest` — init with initial handlers, duplicate
    key fails fast, blank key rejected, unregister removes,
    unregister on unknown returns false, find on missing returns null
  * `DispatchingJavaDelegateTest` — dispatches by currentActivityId,
    throws on missing handler, defensive-copies the variable map
  * `DelegateTaskContextTest` — set non-null forwards, set null
    removes, blank name rejected, principal/locale/correlationId
    passthrough, default correlation id is stable across calls
  * `PingTaskHandlerTest` — key matches the BPMN serviceTask id,
    execute writes pong + pongAt + correlationId
- Total framework unit tests: 261 (was 246), all green.

## What this unblocks

- **REF.1** — real quote→job-card workflow handler in the
  printing-shop plug-in
- **pbc-production routings/operations (v3)** — each operation
  becomes a BPMN step with duration + machine assignment
- **P2.3** — user-task form rendering (landing on top of the
  RuntimeService already exposed via WorkflowService)
- **P2.2** — BPMN designer web page (later, depends on R1)

## Deliberate non-goals (parking lot)

- Principal propagation from the REST caller through the process
  start into the handler — uses a fixed `workflow-engine`
  `Principal.System` for now. Follow-up chunk will plumb the
  authenticated user as a Flowable variable.
- Plug-in-contributed TaskHandler registration via PF4J child
  contexts — the registry exposes `register/unregister` but the
  plug-in loader doesn't call them yet. Follow-up chunk.
- BPMN user tasks, signals, timers, history queries — seam exists,
  deliberately not built out.
- Workflow deployment from `metadata__workflow` rows (the Tier 1
  path). Today deployment is classpath-only via Flowable's auto-
  deployer.
- The Flowable async job executor is explicitly deactivated
  (`flowable.async-executor-activate: false`) — background-job
  machinery belongs to the future Quartz integration (P1.10), not
  Flowable.

The framework's authorization layer is now live. Until now, every
authenticated user could do everything; the framework had only an
authentication gate. This chunk adds method-level @RequirePermission
annotations enforced by a Spring AOP aspect that consults the JWT's
roles claim and a metadata-driven role-permission map.

What landed
-----------
* New `Role` and `UserRole` JPA entities mapping the existing
  identity__role + identity__user_role tables (the schema was
  created in the original identity init but never wired to JPA).
  RoleJpaRepository + UserRoleJpaRepository with a JPQL query that
  returns a user's role codes in one round-trip.
* `JwtIssuer.issueAccessToken(userId, username, roles)` now accepts a
  Set<String> of role codes and encodes them as a `roles` JWT claim
  (sorted for deterministic tests). Refresh tokens NEVER carry roles
  by design — see the rationale on `JwtIssuer.issueRefreshToken`. A
  role revocation propagates within one access-token lifetime
  (15 min default).
* `JwtVerifier` reads the `roles` claim into `DecodedToken.roles`.
  Missing claim → empty set, NOT an error (refresh tokens, system
  tokens, and pre-P4.3 tokens all legitimately omit it).
* `AuthService.login` now calls `userRoles.findRoleCodesByUserId(...)`
  before minting the access token. `AuthService.refresh` re-reads
  the user's roles too — so a refresh always picks up the latest
  set, since refresh tokens deliberately don't carry roles.
* New `AuthorizationContext` ThreadLocal in `platform-security.authz`
  carrying an `AuthorizedPrincipal(id, username, roles)`. Separate
  from `PrincipalContext` (which lives in platform-persistence and
  carries only the principal id, for the audit listener). The two
  contexts coexist because the audit listener has no business
  knowing what roles a user has.
* `PrincipalContextFilter` now populates BOTH contexts on every
  authenticated request, reading the JWT's `username` and `roles`
  claims via `Jwt.getClaimAsStringList("roles")`. The filter is the
  one and only place that knows about Spring Security types AND
  about both vibe_erp contexts; everything downstream uses just the
  Spring-free abstractions.
* `PermissionEvaluator` Spring bean: takes a role set + permission
  key, returns boolean. Resolution chain:
  1. The literal `admin` role short-circuits to `true` for every
     key (the wildcard exists so the bootstrap admin can do
     everything from the very first boot without seeding a complete
     role-permission mapping).
  2. Otherwise consults an in-memory `Map<role, Set<permission>>`
     loaded from `metadata__role_permission` rows. The cache is
     rebuilt by `refresh()`, called from `VibeErpPluginManager`
     after the initial core load AND after every plug-in load.
  3. Empty role set is always denied. No implicit grants.
* `@RequirePermission("...")` annotation in `platform-security.authz`.
  `RequirePermissionAspect` is a Spring AOP @Aspect with @Around
  advice that intercepts every annotated method, reads the current
  request's `AuthorizationContext`, calls
  `PermissionEvaluator.has(...)`, and either proceeds or throws
  `PermissionDeniedException`.
* New `PermissionDeniedException` carrying the offending key.
  `GlobalExceptionHandler` maps it to HTTP 403 Forbidden with
  `"permission denied: 'partners.partner.deactivate'"` as the
  detail. The key IS surfaced to the caller (unlike the 401's
  generic "invalid credentials") because the SPA needs it to
  render a useful "your role doesn't include X" message and
  callers are already authenticated, so it's not an enumeration
  vector.
* `BootstrapAdminInitializer` now creates the wildcard `admin`
  role on first boot and grants it to the bootstrap admin user.
* `@RequirePermission` applied to four sensitive endpoints as the
  demo: `PartnerController.deactivate`,
  `StockBalanceController.adjust`, `SalesOrderController.confirm`,
  `SalesOrderController.cancel`. More endpoints will gain
  annotations as additional roles are introduced; v1 keeps the
  blast radius narrow.

End-to-end smoke test
---------------------
Reset Postgres, booted the app, verified:
* Admin login → JWT length 265 (was 241), decoded claims include
  `"roles":["admin"]`
* Admin POST /sales-orders/{id}/confirm → 200, status DRAFT → CONFIRMED
  (admin wildcard short-circuits the permission check)
* Inserted a 'powerless' user via raw SQL with no role assignments
  but copied the admin's password hash so login works
* Powerless login → JWT length 247, decoded claims have NO roles
  field at all
* Powerless POST /sales-orders/{id}/cancel → **403 Forbidden** with
  `"permission denied: 'orders.sales.cancel'"` in the body
* Powerless DELETE /partners/{id} → **403 Forbidden** with
  `"permission denied: 'partners.partner.deactivate'"`
* Powerless GET /sales-orders, /partners, /catalog/items → all 200
  (read endpoints have no @RequirePermission)
* Admin regression: catalog uoms, identity users, inventory
  locations, printing-shop plates with i18n, metadata custom-fields
  endpoint — all still HTTP 2xx

Build
-----
* `./gradlew build`: 15 subprojects, 163 unit tests (was 153),
  all green. The 10 new tests cover:
  - PermissionEvaluator: empty roles deny, admin wildcard, explicit
    role-permission grant, multi-role union, unknown role denial,
    malformed payload tolerance, currentHas with no AuthorizationContext,
    currentHas with bound context (8 tests).
  - JwtRoundTrip: roles claim round-trips through the access token,
    refresh token never carries roles even when asked (2 tests).

What was deferred
-----------------
* **OIDC integration (P4.2)**. Built-in JWT only. The Keycloak-
  compatible OIDC client will reuse the same authorization layer
  unchanged — the roles will come from OIDC ID tokens instead of
  the local user store.
* **Permission key validation at boot.** The framework does NOT
  yet check that every `@RequirePermission` value matches a
  declared metadata permission key. The plug-in linter is the
  natural place for that check to land later.
* **Role hierarchy**. Roles are flat in v1; a role with permission
  X cannot inherit from another role. Adding a `parent_role` field
  on the role row is a non-breaking change later.
* **Resource-aware permissions** ("the user owns THIS partner").
  v1 only checks the operation, not the operand. Resource-aware
  checks are post-v1.
* **Composite (AND/OR) permission requirements**. A single key
  per call site keeps the contract simple. Composite requirements
  live in service code that calls `PermissionEvaluator.currentHas`
  directly.
* **Role management UI / REST**. The framework can EVALUATE
  permissions but has no first-class endpoints for "create a
  role", "grant a permission to a role", "assign a role to a
  user". v1 expects these to be done via direct DB writes or via
  the future SPA's role editor (P3.x); the wiring above is
  intentionally policy-only, not management.

Adds the foundation for the entire Tier 1 customization story. Core
PBCs and plug-ins now ship YAML files declaring their entities,
permissions, and menus; a `MetadataLoader` walks the host classpath
and each plug-in JAR at boot, upserts the rows tagged with their
source, and exposes them at a public REST endpoint so the future
SPA, AI-agent function catalog, OpenAPI generator, and external
introspection tooling can all see what the framework offers without
scraping code.

What landed:

* New `platform/platform-metadata/` Gradle subproject. Depends on
  api-v1 + platform-persistence + jackson-yaml + spring-jdbc.

* `MetadataYamlFile` DTOs (entities, permissions, menus). Forward-
  compatible: unknown top-level keys are ignored, so a future plug-in
  built against a newer schema (forms, workflows, rules, translations)
  loads cleanly on an older host that doesn't know those sections yet.

* `MetadataLoader` with two entry points:

    loadCore() — uses Spring's PathMatchingResourcePatternResolver
      against the host classloader. Finds every classpath*:META-INF/
      vibe-erp/metadata/*.yml across all jars contributing to the
      application. Tagged source='core'.

    loadFromPluginJar(pluginId, jarPath) — opens ONE specific
      plug-in JAR via java.util.jar.JarFile and walks its entries
      directly. This is critical: a plug-in's PluginClassLoader is
      parent-first, so a classpath*: scan against it would ALSO
      pick up the host's metadata files via parent classpath. We
      saw this in the first smoke run — the plug-in source ended
      up with 6 entities (the plug-in's 2 + the host's 4) before
      the fix. Walking the JAR file directly guarantees only the
      plug-in's own files load. Tagged source='plugin:<id>'.

  Both entry points use the same delete-then-insert idempotent core
  (doLoad). Loading the same source twice produces the same final
  state. User-edited metadata (source='user') is NEVER touched by
  either path — it survives boot, plug-in install, and plug-in
  upgrade. This is what lets a future SPA "Customize" UI add custom
  fields without fearing they'll be wiped on the next deploy.

* `VibeErpPluginManager.afterPropertiesSet()` now calls
  metadataLoader.loadCore() at the very start, then walks plug-ins
  and calls loadFromPluginJar(...) for each one between Liquibase
  migration and start(context). Order is guaranteed: core → linter
  → migrate → metadata → start. The CommandLineRunner I originally
  put `loadCore()` in turned out to be wrong because Spring runs
  CommandLineRunners AFTER InitializingBean.afterPropertiesSet(),
  so the plug-in metadata was loading BEFORE core — the wrong way
  around. Calling loadCore() inline in the plug-in manager fixes
  the ordering without any @Order(...) gymnastics.

* `MetadataController` exposes:
    GET /api/v1/_meta/metadata           — all three sections
    GET /api/v1/_meta/metadata/entities  — entities only
    GET /api/v1/_meta/metadata/permissions
    GET /api/v1/_meta/metadata/menus
  Public allowlist (covered by the existing /api/v1/_meta/** rule
  in SecurityConfiguration). The metadata is intentionally non-
  sensitive — entity names, permission keys, menu paths. Nothing
  in here is PII or secret; the SPA needs to read it before the
  user has logged in.

* YAML files shipped:
  - pbc-identity/META-INF/vibe-erp/metadata/identity.yml
    (User + Role entities, 6 permissions, Users + Roles menus)
  - pbc-catalog/META-INF/vibe-erp/metadata/catalog.yml
    (Item + Uom entities, 7 permissions, Items + UoMs menus)
  - reference plug-in/META-INF/vibe-erp/metadata/printing-shop.yml
    (Plate + InkRecipe entities, 5 permissions, Plates + Inks menus
    in a "Printing shop" section)

Tests: 4 MetadataLoaderTest cases (loadFromPluginJar happy paths,
mixed sections, blank pluginId rejection, missing-file no-op wipe)
+ 7 MetadataYamlParseTest cases (DTO mapping, optional fields,
section defaults, forward-compat unknown keys). Total now
**92 unit tests** across 11 modules, all green.

End-to-end smoke test against fresh Postgres + plug-in loaded:

  Boot logs:
    MetadataLoader: source='core' loaded 4 entities, 13 permissions,
      4 menus from 2 file(s)
    MetadataLoader: source='plugin:printing-shop' loaded 2 entities,
      5 permissions, 2 menus from 1 file(s)

  HTTP smoke (everything green):
    GET /api/v1/_meta/metadata (no auth)              → 200
      6 entities, 18 permissions, 6 menus
      entity names: User, Role, Item, Uom, Plate, InkRecipe
      menu sections: Catalog, Printing shop, System
    GET /api/v1/_meta/metadata/entities                → 200
    GET /api/v1/_meta/metadata/menus                   → 200

  Direct DB verification:
    metadata__entity:    core=4, plugin:printing-shop=2
    metadata__permission: core=13, plugin:printing-shop=5
    metadata__menu:      core=4, plugin:printing-shop=2

  Idempotency: restart the app, identical row counts.

  Existing endpoints regression:
    GET /api/v1/identity/users (Bearer)               → 1 user
    GET /api/v1/catalog/uoms (Bearer)                  → 15 UoMs
    GET /api/v1/plugins/printing-shop/ping (Bearer)    → 200

Bugs caught and fixed during the smoke test:

  • The first attempt loaded core metadata via a CommandLineRunner
    annotated @Order(HIGHEST_PRECEDENCE) and per-plug-in metadata
    inline in VibeErpPluginManager.afterPropertiesSet(). Spring
    runs all InitializingBeans BEFORE any CommandLineRunner, so
    the plug-in metadata loaded first and the core load came
    second — wrong order. Fix: drop CoreMetadataInitializer
    entirely; have the plug-in manager call metadataLoader.loadCore()
    directly at the start of afterPropertiesSet().

  • The first attempt's plug-in load used
    metadataLoader.load(pluginClassLoader, ...) which used Spring's
    PathMatchingResourcePatternResolver against the plug-in's
    classloader. PluginClassLoader is parent-first, so the resolver
    enumerated BOTH the plug-in's own JAR AND the host classpath's
    metadata files, tagging core entities as source='plugin:<id>'
    and corrupting the seed counts. Fix: refactor MetadataLoader
    to expose loadFromPluginJar(pluginId, jarPath) which opens
    the plug-in JAR directly via java.util.jar.JarFile and walks
    its entries — never asking the classloader at all. The
    api-v1 surface didn't change.

  • Two KDoc comments contained the literal string `*.yml` after
    a `/` character (`/metadata/*.yml`), forming the `/*` pattern
    that Kotlin's lexer treats as a nested-comment opener. The
    file failed to compile with "Unclosed comment". This is the
    third time I've hit this trap; rewriting both KDocs to avoid
    the literal `/*` sequence.

  • The MetadataLoaderTest's hand-rolled JAR builder didn't include
    explicit directory entries for parent paths. Real Gradle JARs
    do include them, and Spring's PathMatchingResourcePatternResolver
    needs them to enumerate via classpath*:. Fixed the test helper
    to write directory entries for every parent of each file.

Implementation plan refreshed: P1.5 marked DONE. Next priority
candidates: P5.2 (pbc-partners — third PBC clone) and P3.4 (custom
field application via the ext jsonb column, which would unlock the
full Tier 1 customization story).

Framework state: 17→18 commits, 10→11 modules, 81→92 unit tests,
metadata seeded for 6 entities + 18 permissions + 6 menus.

The reference printing-shop plug-in graduates from "hello world" to a
real customer demonstration: it now ships its own Liquibase changelog,
owns its own database tables, and exposes a real domain (plates and
ink recipes) via REST that goes through `context.jdbc` — a new
typed-SQL surface in api.v1 — without ever touching Spring's
`JdbcTemplate` or any other host internal type. A bytecode linter
that runs before plug-in start refuses to load any plug-in that tries
to import `org.vibeerp.platform.*` or `org.vibeerp.pbc.*` classes.

What landed:

* api.v1 (additive, binary-compatible):
  - PluginJdbc — typed SQL access with named parameters. Methods:
    query, queryForObject, update, inTransaction. No Spring imports
    leaked. Forces plug-ins to use named params (no positional ?).
  - PluginRow — typed nullable accessors over a single result row:
    string, int, long, uuid, bool, instant, bigDecimal. Hides
    java.sql.ResultSet entirely.
  - PluginContext.jdbc getter with default impl that throws
    UnsupportedOperationException so older builds remain binary
    compatible per the api.v1 stability rules.

* platform-plugins — three new sub-packages:
  - jdbc/DefaultPluginJdbc backed by Spring's NamedParameterJdbcTemplate.
    ResultSetPluginRow translates each accessor through ResultSet.wasNull()
    so SQL NULL round-trips as Kotlin null instead of the JDBC defaults
    (0 for int, false for bool, etc. — bug factories).
  - jdbc/PluginJdbcConfiguration provides one shared PluginJdbc bean
    for the whole process. Per-plugin isolation lands later.
  - migration/PluginLiquibaseRunner looks for
    META-INF/vibe-erp/db/changelog.xml inside the plug-in JAR via
    the PF4J classloader and applies it via Liquibase against the
    host's shared DataSource. The unique META-INF path matters:
    plug-ins also see the host's parent classpath, where the host's
    own db/changelog/master.xml lives, and a collision causes
    Liquibase ChangeLogParseException at install time.
  - lint/PluginLinter walks every .class entry in the plug-in JAR
    via java.util.jar.JarFile + ASM ClassReader, visits every type/
    method/field/instruction reference, rejects on any reference to
    `org/vibeerp/platform/` or `org/vibeerp/pbc/` packages.

* VibeErpPluginManager lifecycle is now load → lint → migrate → start:
  - lint runs immediately after PF4J's loadPlugins(); rejected
    plug-ins are unloaded with a per-violation error log and never
    get to run any code
  - migrate runs the plug-in's own Liquibase changelog; failure
    means the plug-in is loaded but skipped (loud warning, framework
    boots fine)
  - then PF4J's startPlugins() runs the no-arg start
  - then we walk loaded plug-ins and call vibe_erp's start(context)
    with a fully-wired DefaultPluginContext (logger + endpoints +
    eventBus + jdbc). The plug-in's tables are guaranteed to exist
    by the time its lambdas run.

* DefaultPluginContext.jdbc is no longer a stub. Plug-ins inject the
  shared PluginJdbc and use it to talk to their own tables.

* Reference plug-in (PrintingShopPlugin):
  - Ships META-INF/vibe-erp/db/changelog.xml with two changesets:
    plugin_printingshop__plate (id, code, name, width_mm, height_mm,
    status) and plugin_printingshop__ink_recipe (id, code, name,
    cmyk_c/m/y/k).
  - Now registers seven endpoints:
      GET  /ping          — health
      GET  /echo/{name}   — path variable demo
      GET  /plates        — list
      GET  /plates/{id}   — fetch
      POST /plates        — create (with race-conditiony existence
                            check before INSERT, since plug-ins
                            can't import Spring's DataAccessException)
      GET  /inks
      POST /inks
  - All CRUD lambdas use context.jdbc with named parameters. The
    plug-in still imports nothing from org.springframework.* in its
    own code (it does reach the host's Jackson via reflection for
    JSON parsing — a deliberate v0.6 shortcut documented inline).

Tests: 5 new PluginLinterTest cases use ASM ClassWriter to synthesize
in-memory plug-in JARs (clean class, forbidden platform ref, forbidden
pbc ref, allowed api.v1 ref, multiple violations) and a mocked
PluginWrapper to avoid touching the real PF4J loader. Total now
**81 unit tests** across 10 modules, all green.

End-to-end smoke test against fresh Postgres with the plug-in loaded
(every assertion green):

  Boot logs:
    PluginLiquibaseRunner: plug-in 'printing-shop' has changelog.xml
    Liquibase: ChangeSet printingshop-init-001 ran successfully
    Liquibase: ChangeSet printingshop-init-002 ran successfully
    Liquibase migrations applied successfully
    plugin.printing-shop: registered 7 endpoints

  HTTP smoke:
    \dt plugin_printingshop*                  → both tables exist
    GET /api/v1/plugins/printing-shop/plates  → []
    POST plate A4                              → 201 + UUID
    POST plate A3                              → 201 + UUID
    POST duplicate A4                          → 409 + clear msg
    GET plates                                 → 2 rows
    GET /plates/{id}                           → A4 details
    psql verifies both rows in plugin_printingshop__plate
    POST ink CYAN                              → 201
    POST ink MAGENTA                           → 201
    GET inks                                   → 2 inks with nested CMYK
    GET /ping                                  → 200 (existing endpoint)
    GET /api/v1/catalog/uoms                   → 15 UoMs (no regression)
    GET /api/v1/identity/users                 → 1 user (no regression)

Bug encountered and fixed during the smoke test:

  • The plug-in initially shipped its changelog at db/changelog/master.xml,
    which collides with the HOST's db/changelog/master.xml. The plug-in
    classloader does parent-first lookup (PF4J default), so Liquibase's
    ClassLoaderResourceAccessor found BOTH files and threw
    ChangeLogParseException ("Found 2 files with the path"). Fixed by
    moving the plug-in changelog to META-INF/vibe-erp/db/changelog.xml,
    a path the host never uses, and updating PluginLiquibaseRunner.
    The unique META-INF prefix is now part of the documented plug-in
    convention.

What is explicitly NOT in this chunk (deferred):

  • Per-plugin Spring child contexts — plug-ins still instantiate via
    PF4J's classloader without their own Spring beans
  • Per-plugin datasource isolation — one shared host pool today
  • Plug-in changelog table-prefix linter — convention only, runtime
    enforcement comes later
  • Rollback on plug-in uninstall — uninstall is operator-confirmed
    and rare; running dropAll() during stop() would lose data on
    accidental restart
  • Subscription auto-scoping on plug-in stop — plug-ins still close
    their own subscriptions in stop()
  • Real customer-grade JSON parsing in plug-in lambdas — the v0.6
    reference plug-in uses reflection to find the host's Jackson; a
    real plug-in author would ship their own JSON library or use a
    future api.v1 typed-DTO surface

Implementation plan refreshed: P1.2, P1.3, P1.4, P1.7, P4.1, P5.1
all marked DONE in
docs/superpowers/specs/2026-04-07-vibe-erp-implementation-plan.md.
Next priority candidates: P1.5 (metadata seeder) and P5.2 (pbc-partners).

Adds the framework's event bus, the second cross-cutting service (after
auth) that PBCs and plug-ins both consume. Implements the transactional
outbox pattern from the architecture spec section 9 — events are
written to the database in the same transaction as the publisher's
domain change, so a publish followed by a rollback never escapes.
This is the seam where a future Kafka/NATS bridge plugs in WITHOUT
touching any PBC code.

What landed:

* New `platform/platform-events/` module:
  - `EventOutboxEntry` JPA entity backed by `platform__event_outbox`
    (id, event_id, topic, aggregate_type, aggregate_id, payload jsonb,
    status, attempts, last_error, occurred_at, dispatched_at, version).
    Status enum: PENDING / DISPATCHED / FAILED.
  - `EventOutboxRepository` Spring Data JPA repo with a pessimistic
    SELECT FOR UPDATE query for poller dispatch.
  - `ListenerRegistry` — in-memory subscription holder, indexed both
    by event class (Class.isInstance) and by topic string. Supports
    a `**` wildcard for the platform's audit subscriber. Backed by
    CopyOnWriteArrayList so dispatch is lock-free.
  - `EventBusImpl` — implements the api.v1 EventBus. publish() writes
    the outbox row AND synchronously delivers to in-process listeners
    in the SAME transaction. Marked Propagation.MANDATORY so the bus
    refuses to publish outside an existing transaction (preventing
    publish-and-rollback leaks). Listener exceptions are caught and
    logged; the outbox row still commits.
  - `OutboxPoller` — Spring @Scheduled component that runs every 5s,
    drains PENDING / FAILED rows under a pessimistic lock, marks them
    DISPATCHED. v0.5 has no real external dispatcher — the poller is
    the seam where Kafka/NATS plugs in later.
  - `EventBusConfiguration` — @EnableScheduling so the poller actually
    runs. Lives in this module so the seam activates automatically
    when platform-events is on the classpath.
  - `EventAuditLogSubscriber` — wildcard subscriber that logs every
    event at INFO. Demo proof that the bus works end-to-end. Future
    versions replace it with a real audit log writer.

* `platform__event_outbox` Liquibase changeset (platform-events-001):
  table + unique index on event_id + index on (status, created_at) +
  index on topic.

* DefaultPluginContext.eventBus is no longer a stub that throws —
  it's now the real EventBus injected by VibeErpPluginManager.
  Plug-ins can publish and subscribe via the api.v1 surface. Note:
  subscriptions are NOT auto-scoped to the plug-in lifecycle in v0.5;
  a plug-in that wants its subscriptions removed on stop() must call
  subscription.close() explicitly. Auto-scoping lands when per-plug-in
  Spring child contexts ship.

* pbc-identity now publishes `UserCreatedEvent` after a successful
  UserService.create(). The event class is internal to pbc-identity
  (not in api.v1) — other PBCs subscribe by topic string
  (`identity.user.created`), not by class. This is the right tradeoff:
  string topics are stable across plug-in classloaders, class equality
  is not, and adding every event class to api.v1 would be perpetual
  surface-area bloat.

Tests: 13 new unit tests (9 EventBusImplTest + 4 OutboxPollerTest)
plus 2 new UserServiceTest cases that verify the publish happens on
the happy path and does NOT happen when create() rejects a duplicate.
Total now 76 unit tests across the framework, all green.

End-to-end smoke test against fresh Postgres with the plug-in loaded
(everything green):

  EventAuditLogSubscriber subscribed to ** at boot
  Outbox empty before any user create                      ✓
  POST /api/v1/auth/login                                  → 200
  POST /api/v1/identity/users (create alice)               → 201
  Outbox row appears with topic=identity.user.created,
    status=PENDING immediately after create                ✓
  EventAuditLogSubscriber log line fires synchronously
    inside the create transaction                          ✓
  POST /api/v1/identity/users (create bob)                 → 201
  Wait 8s (one OutboxPoller cycle)
  Both outbox rows now DISPATCHED, dispatched_at set       ✓
  Existing PBCs still work:
    GET /api/v1/identity/users → 3 users                   ✓
    GET /api/v1/catalog/uoms → 15 UoMs                     ✓
  Plug-in still works:
    GET /api/v1/plugins/printing-shop/ping → 200           ✓

The most important assertion is the synchronous audit log line
appearing on the same thread as the user creation request. That
proves the entire chain — UserService.create() → eventBus.publish()
→ EventBusImpl writes outbox row → ListenerRegistry.deliver()
finds wildcard subscriber → EventAuditLogSubscriber.handle()
logs — runs end-to-end inside the publisher's transaction.
The poller flipping PENDING → DISPATCHED 5s later proves the
outbox + poller seam works without any external dispatcher.

Bug encountered and fixed during the smoke test:

  • EventBusImplTest used `ObjectMapper().registerKotlinModule()`
    which doesn't pick up jackson-datatype-jsr310. Production code
    uses Spring Boot's auto-configured ObjectMapper which already
    has jsr310 because spring-boot-starter-web is on the classpath
    of distribution. The test setup was the only place using a bare
    mapper. Fixed by switching to `findAndRegisterModules()` AND
    by adding jackson-datatype-jsr310 as an explicit implementation
    dependency of platform-events (so future modules that depend on
    the bus without bringing web in still get Instant serialization).

What is explicitly NOT in this chunk:

  • External dispatcher (Kafka/NATS bridge) — the poller is a no-op
    that just marks rows DISPATCHED. The seam exists; the dispatcher
    is a future P1.7.b unit.
  • Exponential backoff on FAILED rows — every cycle re-attempts.
    Real backoff lands when there's a real dispatcher to fail.
  • Dead-letter queue — same.
  • Per-plug-in subscription auto-scoping — plug-ins must close()
    explicitly today.
  • Async / fire-and-forget publish — synchronous in-process only.

Implements the auth unit from the implementation plan. Until now, the
framework let any caller hit any endpoint; with the single-tenant
refactor there is no second wall, so auth was the most pressing gap.

What landed:

* New `platform-security` module owns the framework's security
  primitives (JWT issuer/verifier, password encoder, Spring Security
  filter chain config, AuthenticationFailedException). Lives between
  platform-persistence and platform-bootstrap.

* `JwtIssuer` mints HS256-signed access (15min) and refresh (7d) tokens
  via NimbusJwtEncoder. `JwtVerifier` decodes them back to a typed
  `DecodedToken` so PBCs never need to import OAuth2 types. JWT secret
  is read from VIBEERP_JWT_SECRET; the framework refuses to start if
  the secret is shorter than 32 bytes.

* `SecurityConfiguration` wires Spring Security with JWT resource
  server, stateless sessions, CSRF disabled, and a public allowlist
  for /actuator/health, /actuator/info, /api/v1/_meta/**,
  /api/v1/auth/login, /api/v1/auth/refresh.

* `PrincipalContext` (in platform-persistence/security) is the bridge
  between Spring Security's SecurityContextHolder and the audit
  listener. Bound by `PrincipalContextFilter` which runs AFTER
  BearerTokenAuthenticationFilter so SecurityContextHolder is fully
  populated. The audit listener (AuditedJpaEntityListener) now reads
  from PrincipalContext, so created_by/updated_by are real user ids
  instead of __system__.

* `pbc-identity` gains `UserCredential` (separate table from User —
  password hashes never share a query plan with user records),
  `AuthService` (login + refresh, generic AuthenticationFailedException
  on every failure to thwart account enumeration), and `AuthController`
  exposing /api/v1/auth/login and /api/v1/auth/refresh.

* `BootstrapAdminInitializer` runs on first boot of an empty
  identity__user table, creates an `admin` user with a random
  16-char password printed to the application logs. Subsequent
  boots see the user exists and skip silently.

* GlobalExceptionHandler maps AuthenticationFailedException → 401
  with a generic "invalid credentials" body (RFC 7807 ProblemDetail).

* New module also brings BouncyCastle as a runtime-only dep
  (Argon2PasswordEncoder needs it).

Tests: 38 unit tests pass, including JwtRoundTripTest (issue/decode
round trip + tamper detection + secret-length validation),
PrincipalContextTest (ThreadLocal lifecycle), AuthServiceTest (9 cases
covering login + refresh happy paths and every failure mode).

End-to-end smoke test against a fresh Postgres via docker-compose:
  GET /api/v1/identity/users (no auth)        → 401
  POST /api/v1/auth/login (admin + bootstrap) → 200 + access/refresh
  POST /api/v1/auth/login (wrong password)    → 401
  GET  /api/v1/identity/users (Bearer)        → 200, lists admin
  POST /api/v1/identity/users (Bearer)        → 201, creates alice
  alice.created_by                            → admin's user UUID
  POST /api/v1/auth/refresh (refresh token)   → 200 + new pair
  POST /api/v1/auth/refresh (access token)    → 401 (type mismatch)
  GET  /api/v1/identity/users (garbage token) → 401
  GET  /api/v1/_meta/info (no auth, public)   → 200

Plan: docs/superpowers/specs/2026-04-07-vibe-erp-implementation-plan.md
refreshed to drop the now-dead P1.1 (RLS hook) and H1 (per-region
tenant routing), reorder priorities so P4.1 is first, and reflect the
single-tenant change throughout.

Bug fixes encountered along the way (caught by the smoke test, not by
unit tests — the value of running real workflows):

  • JwtIssuer was producing IssuedToken.expiresAt with nanosecond
    precision but JWT exp is integer seconds; the round-trip test
    failed equality. Fixed by truncating to ChronoUnit.SECONDS at
    issue time.
  • PrincipalContextFilter was registered with addFilterAfter
    UsernamePasswordAuthenticationFilter, which runs BEFORE the
    OAuth2 BearerTokenAuthenticationFilter, so SecurityContextHolder
    was empty when the bridge filter read it. Result: every
    authenticated request still wrote __system__ in audit columns.
    Fixed by addFilterAfter BearerTokenAuthenticationFilter::class.
  • RefreshRequest is a single-String data class. jackson-module-kotlin
    interprets single-arg data classes as delegate-based creators, so
    Jackson tried to deserialize the entire JSON object as a String
    and threw HttpMessageNotReadableException. Fixed by adding
    @JsonCreator(mode = PROPERTIES) + @param:JsonProperty.