marcel/familienarchiv
1
0
Fork 0
Code Issues 126 Pull Requests 1 Actions Packages Projects Releases Wiki Activity

docs(adr): add ADR-001 (OCR microservice) and ADR-002 (polygon JSONB)

Browse Source 
ADR-001 documents the decision to use a separate Python container for
OCR (Surya + Kraken), the interface contract, and why alternatives
like Tess4J were rejected.

ADR-002 documents the decision to store polygon annotations as JSONB
with a 4-point CHECK constraint, backed by an AttributeConverter.

Refs #226, #227

Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
This commit is contained in:
Marcel
2026-04-12 15:07:46 +02:00
parent 11a35f2952
commit ec32d225b5
2 changed files with 136 additions and 0 deletions
Download Patch File Download Diff File Expand all files Collapse all files

84
docs/adr/001-ocr-python-microservice.md Normal file
View File

@@ -0,0 +1,84 @@
# ADR-001: OCR Python Microservice
## Status
Accepted
## Context
The Familienarchiv needs OCR capability to pre-populate transcription blocks from scanned documents. Two OCR engines are required:
- **Surya** — transformer-based, handles typewritten and modern Latin handwriting
- **Kraken** — historical HTR model support, required for pre-1941 German Kurrent/Suetterlin scripts
Both engines exist exclusively in the Python ecosystem. There are no production-quality Java bindings for either engine. Tess4J (Tesseract for Java) was considered but rejected: Tesseract has poor accuracy on degraded historical handwriting and no HTR-United model support.
The server has no GPU. CPU-only inference is the target (16-32 GB system RAM).
## Decision
Introduce a separate Python container (`ocr-service`) that exposes a simple HTTP API. Spring Boot calls this service via `RestClient`. The Python service is stateless — all job tracking and business logic remain in Spring Boot.
**Interface contract:**
Request:
```json
{
"pdfUrl": "http://minio:9000/archive-documents/abc.pdf?presigned...",
"scriptType": "HANDWRITING_KURRENT",
"language": "de"
}
```
Response:
```json
[
{
"pageNumber": 0,
"x": 0.12, "y": 0.08, "width": 0.76, "height": 0.04,
"polygon": [[0.12,0.08],[0.88,0.09],[0.87,0.12],[0.13,0.11]],
"text": "Sehr geehrter Herr ..."
}
]
```
Coordinates are normalized (0-1) relative to page dimensions.
**Java-side integration:**
- `OcrClient` interface with `extractBlocks()` method — mockable for unit tests
- `OcrHealthClient` interface with `isHealthy()` — separate concern from block extraction
- `RestClientOcrClient` implements both interfaces
- `OcrService` orchestrates: presigned URL generation, OCR call, block mapping, TranscriptionService delegation
**Docker networking:**
- `ocr-service` is on the internal Docker network only — no host port mapping
- Spring Boot reaches it via `http://ocr-service:8000`
- Health check with `start_period: 60s` to account for model loading (~30-60s on CPU)
## Alternatives Considered
| Alternative | Why rejected |
|---|---|
| Tess4J (Tesseract in Java) | No HTR-United model support; poor Kurrent accuracy |
| Calling Python via ProcessBuilder | Fragile, no health checks, model reloading on every call |
| Embedding Python via GraalVM | Experimental, complex dependency management for ML libraries |
| External SaaS OCR (Google Vision, AWS Textract) | Data sovereignty concern for private family documents; no Kurrent support |
## Consequences
**Easier:**
- Each engine is used via its native Python API — no bridging complexity
- OCR service can be updated independently of the main application
- Models can be swapped via volume mount without code changes
**Harder:**
- One additional container to operate (memory, health checks, restarts)
- Integration tests require WireMock stub — real OCR service is too slow for CI
- Presigned URL TTL must be managed (15-30 min recommended)
## Future Direction
- LISTEN/NOTIFY from PostgreSQL to push progress events when scaling to multiple instances
- GPU acceleration if the server is upgraded — only the Docker image needs to change

52
docs/adr/002-polygon-jsonb-storage.md Normal file
View File

@@ -0,0 +1,52 @@
# ADR-002: Polygon JSONB Storage for Annotations
## Status
Accepted
## Context
Document annotations currently store axis-aligned bounding boxes (`x, y, width, height`). Kraken OCR outputs polygon boundaries for text lines — historical handwriting (Kurrent, Suetterlin) produces rotated and curved text that axis-aligned rectangles approximate poorly.
We need to store an optional quadrilateral (4 corner points) per annotation to represent the precise text region. The polygon is display-only — overlap detection and all server-side geometry logic continues to use the AABB fields.
## Decision
Add a `polygon JSONB` column to `document_annotations`:
```sql
ALTER TABLE document_annotations ADD COLUMN polygon JSONB;
ALTER TABLE document_annotations
ADD CONSTRAINT chk_annotation_polygon_quad
CHECK (polygon IS NULL OR jsonb_array_length(polygon) = 4);
```
- `null` means rectangle — render using existing `x, y, width, height` fields (fully backward compatible)
- Non-null value is a normalized 4-point quadrilateral: `[[x1,y1],[x2,y2],[x3,y3],[x4,y4]]` with coordinates in the 0-1 range relative to page dimensions
The existing AABB fields are always populated (even when a polygon is present) and remain the authoritative geometry for overlap detection.
**Java entity:** `List<List<Double>> polygon` backed by a custom `AttributeConverter<List<List<Double>>, String>`. No new dependency (Hypersistence Utils is not in the project and won't be added for a single column).
**Semantic invariant:** `polygon`, if present, is a 4-point quadrilateral with coordinates normalized to [0, 1] relative to page dimensions. It may originate from OCR engine output (Kraken) or from a future manual drawing tool. The AABB fields remain the geometry source of truth for server-side logic.
## Alternatives Considered
| Alternative | Why rejected |
|---|---|
| 8 `NUMERIC(8,6)` columns (x1,y1,...,x4,y4) | Verbose, no structural enforcement, awkward to query or extend |
| Separate `annotation_polygons` join table | Unnecessary complexity for a 1:1 optional relationship |
| PostGIS geometry column | Adds a heavyweight extension for a display-only field with no spatial queries |
| `String polygon` on the entity | Requires manual parsing at every callsite; error-prone |
## Consequences
**Easier:**
- Backward compatible — all existing annotations continue to work unchanged
- Frontend renders `<polygon>` or `<rect>` based on a simple null check
- Schema can accommodate N-point polygons in the future (JSONB is flexible), though the CHECK constraint currently enforces exactly 4
**Harder:**
- Cannot express range checks (`0 <= x <= 1`) as database constraints without a PL/pgSQL function — validated at the DTO layer instead
- No server-side geometry queries on polygon coordinates (acceptable — polygon is display-only)
- AttributeConverter adds a small amount of serialization code to maintain