openscribe/state/ARCHITECTURE.md
Laurence 51321aa7c5
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feat(server): pluggable AI providers - any open-standard or commercial AI
Lets the owner point transcription and summarisation at any AI: an open-standard
endpoint (OpenAI-compatible / local faster-whisper / Ollama) or a commercial API
(OpenAI, Anthropic, Gemini). Config-driven, self-hostable, no lock-in.

What changed:
- server/app/providers/: provider layer.
  - base.py: Transcriber/Summariser protocols + shared summary prompt + tolerant JSON
    parser (uniform Summary shape across providers).
  - summary.py: OpenAICompatibleSummariser (any /chat/completions - OpenAI, Groq,
    OpenRouter, LocalAI, LM Studio, vLLM, Ollama /v1) and AnthropicSummariser (Claude
    via the official anthropic SDK; Messages API has no OpenAI-compatible endpoint).
  - transcription.py: OpenAICompatibleTranscriber (/audio/transcriptions - OpenAI,
    Groq, self-hosted whisper server) and LocalWhisperTranscriber (faster-whisper,
    execution wired in M5).
  - factory.py: builds the configured providers with per-provider defaults
    (anthropic -> claude-opus-4-8, openai_compatible -> gpt-4o-mini, ollama -> llama3.1).
- config.py + .env.example: transcription_provider / llm_provider selectors + base_url,
  key, model settings; local faster-whisper and Ollama kept as the self-hosted defaults.
- main.py: /health now reports the resolved provider names (no secrets).
- requirements.txt: httpx drives all HTTP providers; anthropic + faster-whisper are
  optional, only for their respective providers.
- docs/ai-providers.md: config recipes for OpenAI, Groq, Anthropic, Gemini, LocalAI,
  LM Studio, Ollama, self-hosted whisper.
- state/: DECISIONS, ARCHITECTURE, TODO updated.

Why:
- The user asked to connect the device to any open standard AI or commercial one; this
  is also the core differentiator vs Plaud's locked cloud.

Notes:
- Anthropic provider uses the official SDK and defaults to claude-opus-4-8 (per the
  claude-api guidance). AI deps are optional per chosen provider. Modules byte-compile
  cleanly; end-to-end wiring into the ingest pipeline lands with M5.

Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
2026-07-03 18:56:58 +01:00

6.6 KiB

Architecture

How the system is built and why. Update this when the structure changes; a change is not finished until this reflects it.

Overview

Four parts, connected by an open REST API and a shared recording data model:

  [ Device: ESP32-S3 ]                          [ Self-hosted server ]
   mic -> I2S -> ring buffer (PSRAM)             FastAPI
        -> encoder (WAV) -> microSD              +-- ingest (from cloud store / upload)
   button/LED/haptic UX                          +-- faster-whisper (transcribe)
   power + charge detect                         +-- Ollama LLM (summarise)
   |  BLE (control/provision)                    +-- object store (MinIO/local) + DB
   |  WiFi REST API (LAN)                         `-- open REST API + exports
   |  WiFi uploader (on charge) --> cloud store -----------^
                     |                                     |
                     v                                     v
            [ Flutter app: Android + iOS ] <---- open REST API (device + server)

Three sync paths, exactly as specified:

  1. BLE: control, status, and WiFi provisioning (small data). Portable/battery mode.
  2. WiFi to app: bulk recording transfer via the device REST API (fast).
  3. Independent WiFi upload: when on charge / hard-powered the device auto-joins WiFi and pushes recordings to generic cloud storage with no phone present.

Components

firmware (device)

  • Responsibility: capture audio, store it, manage power/controls, expose control + data over BLE and WiFi, and upload autonomously when powered.
  • Location: firmware/ (PlatformIO, Arduino-ESP32, target ESP32-S3).
  • Modules (M1 landed: audio, storage, recorder, ux; rest planned per milestone):
    • audio - I2S/PDM mic capture presenting 16-bit PCM mono (ESP_I2S). [M1]
    • storage- microSD (FAT) streaming WAV writer + sidecar JSON metadata. [M1]
    • recorder - session state machine (idle/recording), file naming, metadata. [M1]
    • ux - button (short-press start/stop) + status LED (haptic later). [M1]
    • power - battery read (ADC), charge/VBUS detect -> mode switch.
    • config - NVS-stored settings (device id, WiFi creds, api token, upload). [M2]
    • net_wifi - WiFi station join/reconnect + SoftAP provisioning fallback + mDNS. [M2]
    • api_http - on-device REST server implementing the device paths. [M2]
    • uploader - S3-compatible / WebDAV client; pushes audio + metadata when powered.
    • ble - GATT: device info, battery, record control, WiFi provisioning, status.
    • ota - firmware update over HTTP.
  • Depends on: microSD, I2S mic, LiPo + charge IC (see hardware/BOM.md).
  • Why this way: ESP32-S3 has WiFi + BLE 5 + PSRAM + USB in one cheap chip, so all three sync paths and audio buffering fit on one board with off-the-shelf modules.

server (self-hosted AI)

  • Responsibility: ingest recordings, transcribe, summarise, store, and serve the open API with exports.
  • Location: server/ (FastAPI).
  • Pipeline: ingest (from cloud store or direct upload) -> store raw audio (object store) -> transcribe (faster-whisper) -> summarise (Ollama LLM) -> index metadata (DB) -> expose REST API + exports (audio, TXT, SRT, VTT, Markdown, JSON).
  • AI is provider-pluggable (server/app/providers/, see docs/ai-providers.md): transcription and the LLM each target a configured provider - open-standard (OpenAI-compatible / local faster-whisper / Ollama) or commercial (OpenAI, Anthropic, Gemini). No lock-in.
  • Depends on: object storage (MinIO or local FS), a DB (SQLite to start, Postgres later), and whichever AI providers are configured (default: self-hosted faster-whisper + Ollama).
  • Why this way: keeps the device cheap and low-power (no on-device AI); all heavy compute runs on hardware the user owns; every step swappable and open.

app (Flutter)

  • Responsibility: provision the device, browse the library, play audio, show transcripts and summaries, export/share, manage settings.
  • Location: app/.
  • Depends on: device BLE + REST API (provisioning/transfer) and server REST API (library, transcripts, summaries).
  • Why this way: one codebase for Android + iOS. iOS restricts background BLE, so BLE is used for control/provisioning and WiFi for bulk transfer, which matches the design.

case (3D print)

  • Responsibility: enclosure for the chosen board + battery + mic + button + USB + LED.
  • Location: case/ (OpenSCAD, parametric).
  • Why this way: code-defined parametric model re-tunes to exact module dimensions and stays fully open and diffable.

hardware

  • Responsibility: BOM, wiring/pinout, build notes. No custom PCB in v1.
  • Location: hardware/.

api

  • Responsibility: the single source of truth for the open API (device + server).
  • Location: api/openapi.yaml.

Data and state

Recording metadata (sidecar JSON on device; row in server DB), canonical shape:

{
  "id": "rec_20260703T101500Z_ab12",
  "device_id": "openscribe-abc123",
  "started_at": "2026-07-03T10:15:00Z",
  "duration_s": 372.5,
  "sample_rate": 16000,
  "channels": 1,
  "codec": "wav_pcm_s16le",
  "size_bytes": 11920000,
  "sha256": "…",
  "source": "device",
  "sync_state": "local | uploaded | ingested | transcribed | summarised",
  "transcript_ref": null,
  "summary_ref": null
}
  • On device: files on microSD (/recordings/<id>.wav + <id>.json); config + secrets in NVS (never on the SD card in clear).
  • In transit: audio + metadata JSON uploaded to the configured object store; server ingests from there (or accepts direct upload).
  • On server: audio + artefacts (transcript, summary, subtitle files) in the object store; metadata + refs in the DB.

External dependencies

  • ESP32-S3 (Espressif), Arduino-ESP32, PlatformIO - mature, free, WiFi + BLE + PSRAM.
  • faster-whisper (CTranslate2) - fast self-hosted STT, CPU or GPU.
  • Ollama - self-hosted local LLM runtime for summaries.
  • MinIO (or any S3-compatible / WebDAV target) - self-hosted object storage.
  • FastAPI, Flutter - open, well supported. All chosen to be self-hostable and open; no required proprietary SaaS.

Constraints and trade-offs

  • Audio default is WAV PCM 16 kHz mono for simplicity and quality; larger files, so WiFi is the real transfer channel and Opus/ADPCM is a later size optimisation.
  • No on-device transcription: keeps the device cheap/low-power; needs the server for AI.
  • BLE bulk transfer is slow and iOS-restricted, so BLE only does control/provisioning and hands transfers to WiFi.
  • v1 uses off-the-shelf modules (no PCB): easier to build, bigger case than a Plaud.
  • Security: device REST API and config writes must be authenticated (token in NVS); independent uploads use scoped object-store credentials. Hardening tracked in TODO.