doc: implementation plan

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 # blekin — implementation plan
 A Rust proxy that translates the Belkin OmniView Remote IP Manager's e-RIC RFB
 protocol (Peppercon LARA, served over a Java applet) into a modern HTML5 KVM
 console. The proxy speaks plain TCP to the OmniView, decodes the proprietary
 8bpp protocol to RGBA, and bridges to a Vite/React frontend over WebSocket.
 All Java references are paths under `~/rc-src/nn/pp/rc/` from the CFR-decompiled
 `rc.jar`. Line numbers reference the files as uploaded.
 ## Target architecture
 ```
 Browser (Vite + React + TS)
   │ WebSocket (binary, RGBA blits + input events)
   ▼
 blekin (Rust, tokio + axum)
   │ HTTP session (cookie + APPLET_ID extraction)
   │ TCP to OmniView:443 (e-RIC RFB)
   ▼
 Belkin OmniView Remote IP Manager
 ```
 Workspace layout:
 ```
 blekin/
 ├── Cargo.toml                     # workspace
 ├── crates/
 │   ├── ericrfb/                   # pure protocol library, no IO
 │   ├── ericrfb-proxy/             # tokio service: HTTP login + TCP + WS bridge
 │   └── ericrfb-frontend/          # Vite/React/TS canvas client
 └── PLAN.md
 ```
 ## Protocol reference (one-page summary)
 Every byte derives from `aw.java`, `ac.java`, and `ByteColorRFBRenderer.java`.
 **Wire facts:**
 - Read primitives are mixed: u8, u16-BE, varint (1–3 bytes, per `aw.int()` at
  line 484). Write primitives are u8 and u16-BE only.
 - Pixel format is **8bpp RGB332** (mask 7 / 56 / 192). One byte per pixel on
  the wire. Decoded to 24-bit RGB via a 256-entry lookup table.
 - Four hardcoded sub-palettes referenced by Hextile/Tight: 1bpp B/W, 2bpp gray,
  4bpp gray, 4bpp 16-color. See `ByteColorRFBRenderer.case()` at line 691.
 - Four parallel zlib streams (`Inflater[4]`) for Tight + encoding 9, indexed by
  bits 4–5 of the encoding control byte. State persists across rectangles —
  rectangles **must not be skipped**.
 **Handshake** (`aw.g()` at line 226):
 | Step | Direction | Bytes | Source |
 |------|-----------|-------|--------|
 | 1 | C→S | 75 bytes: `"e-RIC AUTH=" + APPLET_ID`, zero-padded, ISO-8859-1 | line 259 |
 | 2 | S→C | 1 byte status. `101 ('e')` = OK. `3` = error (read 4 more, see `aw.a(int)`) | line 264 |
 | 3 | S→C | 15 bytes: `"-RIC RFB MM.NN\n"` (digits ASCII) | `int(by)` line 395 |
 | 4 | S→C | 1 byte sync (`w.new()`) | line 270 |
 | 5 | S→C | varint length + N bytes server name | `l()` line 413 |
 | 6 | S→C | 1 byte sync | line 272 |
 | 7 | S→C | 25 bytes pixel-format-ish struct | `i()` line 519 |
 | 8 | C→S | 16 bytes: `"e-RIC RFB " + PROTOCOL_VERSION + "\n"` | `try()` line 405 |
 | 9 | C→S | 2 bytes: `[shared_flag, port_id]` | `char()` line 425 |
 | 10 | S→C | 1 byte sync | line 276 |
 | 11 | S→C | 16 bytes ServerInit: `[bX, w_u16, h_u16, bE, a, try, a3, x_u16, ao_u16, v_u16, bM, bW, bU, 3 pad]` | `k()` line 435 |
 After step 11, the client sends `SetEncodings` and a non-incremental
 `FramebufferUpdateRequest`, then enters the message dispatch loop.
 **Server-to-client message types** (from `ac.char()` switch at line 244 of
 `ac.java`):
 | Type | Reader | Purpose |
 |------|--------|---------|
 | 0 | `ac.f()` → `ac.e()` | FramebufferUpdate |
 | 1 | — | SetColourMapEntries (rejected) |
 | 2 | — | Bell |
 | 3 | `aw.goto()` | ServerCutText |
 | 7 | `aw.l()` | server-name update |
 | 8 | `aw.e()` | pixel-format change (reads 25-byte struct) |
 | 9 | `aw.else()` | layout/locale string |
 | 16 | `aw.i()` | desktop resize + name |
 | 17 | `aw.for()` | 2-byte ack (no-op) |
 | 128 | `aw.k()` | mode change / framebuffer reinit |
 | 131 | `aw.d()` | debug string |
 | 132 | `aw.long()` | RFB-command channel: two strings (key, value) |
 | 148 | `aw.b()` | **ping** — must respond with `aw.if(0)` (msg 149) |
 | 150 | `aw.do()` | bandwidth measurement probe |
 | 161 | `aw.case()` | RDP/Host-Direct mode events |
 **Per-rectangle encoding dispatch** (`ac.e()` at line 233 of `ac.java`):
 | Encoding | Renderer method | Notes |
 |----------|-----------------|-------|
 | 0 | `ByteColorRFBRenderer.if()` line 98 | Raw 8bpp, w×h bytes |
 | 1 | `ByteColorRFBRenderer.a()` line 165 | CopyRect |
 | 5 | `ByteColorRFBRenderer.int()` line 169 | Hextile (16×16, palette refs) |
 | 7 | `ByteColorRFBRenderer.a()` line 244 → 324 | Tight-derived |
 | 9 | `ByteColorRFBRenderer.do()` line 248 | IIP — defer |
 | 10 | `ByteColorRFBRenderer.for()` line 109 | Raw with tile-interleave flag |
 **Client-to-server messages** (writers in `aw.java`):
 | Byte | Method | Format |
 |------|--------|--------|
 | 1 | `a(...)` line 572 | SetPixelFormat |
 | 2 | `a(int[], int)` line 597 | SetEncodings |
 | 3 | `a(...)` line 562 | FramebufferUpdateRequest |
 | 4 | `a(byte)` line 655 | KeyEvent (partial — see Phase 5) |
 | 5 | `a(false,...)` line 612 | PointerEvent: `[5, mask, x_u16, y_u16]` |
 | 7 | `a(String)` line 418 | ClientCutText |
 | 149 | `if(int)` line 636 | PingResponse `[149, 0,0,0, n_u32]` |
 ---
 ## Phase 0 — Repo & scaffolding
 **Goal:** Empty workspace compiles. CI runs `cargo test`.
 - [ ] `cargo new --lib crates/ericrfb`
 - [ ] `cargo new --bin crates/ericrfb-proxy`
 - [ ] Vite scaffold for `crates/ericrfb-frontend` (`npm create vite@latest -- --template react-swc-ts`)
 - [ ] Workspace `Cargo.toml` pinning `tokio = "1"`, `axum = "0.7"`, `bytes = "1"`,
      `flate2 = "1"`, `tracing = "0.1"`, `anyhow`, `thiserror`
 - [ ] `.envrc` / direnv with `RUST_LOG=ericrfb=debug,ericrfb_proxy=debug`
 - [ ] Forgejo Actions workflow on git.lair.cafe: build + test + clippy
 **Deliverable:** `cargo test` green on a stub test in each crate.
 ---
 ## Phase 1 — Protocol primitives (`ericrfb/src/proto.rs`)
 **Goal:** Faithful Rust port of `aw.java`'s read/write helpers. No I/O — all
 operations on `&mut impl AsyncRead` / `&mut impl AsyncWrite` (or `Buf`/`BufMut`
 for unit tests).
 **Java references:**
 - `aw.int()` line 484 — varint, 1–3 bytes, top bit = continuation. **The single
  most important primitive; document it in a code comment with the exact byte
  examples.**
 - `aw.new()` line 454 — `read_u8`
 - `h.try()`, `h.do()`, `h.char()`, `h.byte()` — wrapped i8/u8/i16/string reads
  through the `h.java` adapter class. Map to `read_u8`, `read_u16_be`,
  read-length-prefixed-string.
 - `aw.f()` line 468 — rectangle header reader (varint x, varint y, varint w,
  varint h, u8 encoding). **Critical — these coords are varints, not u16.**
 **Tasks:**
 - [ ] `read_varint` / `write_*` primitives with property tests
 - [ ] `RectHeader { x: u32, y: u32, w: u32, h: u32, encoding: u8 }`
 - [ ] Length-prefixed-string reader with `ISO-8859-1` decode
 - [ ] Unit tests using fixed byte vectors — at least one for each primitive
 **Deliverable:** `cargo test -p ericrfb proto::` covers every primitive used
 later, with a property test ensuring `write_varint(n) → read_varint = n`
 roundtrips for n ∈ [0, 2²²).
 ---
 ## Phase 2 — Handshake (`ericrfb/src/handshake.rs`)
 **Goal:** Open a TCP socket to the OmniView, complete steps 1–11 of the table
 above, return a `Session` containing `(width, height, pixel_format, name,
 read_half, write_half)`.
 **Java references:**
 - `aw.g()` line 226 — the connect-and-handshake sequence in full
 - `aw.int(byte)` line 395 — server-version banner parser
 - `aw.try()` line 405 — client version reply (`"e-RIC RFB 01.11\n"`, exactly 16
  bytes)
 - `aw.char()` line 425 — 2-byte port-init message
 - `aw.k()` line 435 — ServerInit reader
 - `aw.i()` line 519 — pixel-format struct reader
 - `aw.a(int)` line 350 — error code → string (1=no perm, 2=exclusive, 6=auth
  failed, etc.)
 **Tasks:**
 - [ ] `Config { host, port, applet_id, protocol_version, port_id, shared }`
 - [ ] `connect(cfg) -> Result<Session>` walking all 11 steps with `tracing`
      spans
 - [ ] Error type mapping the auth status code via `aw.a(int)`'s table
 - [ ] Integration test gated behind `OMNIVIEW_TEST_HOST` env var that exercises
      the real device — skipped in normal CI
 **Deliverable:** `cargo run --example handshake -- --host 10.3.0.130 --applet-id $TOKEN`
 prints `Connected: name="Remote IP Manager", 640×480, RGB332` and exits cleanly.
 First real-protocol milestone.
 ---
 ## Phase 3 — Session pump + Raw decoder (`ericrfb/src/codec/raw.rs`)
 **Goal:** Receive a `FramebufferUpdate` containing only Raw rectangles, apply
 to a `Framebuffer { width, height, pixels: Vec<u8> }` (8bpp), expand to RGBA via
 LUT, write a PNG to disk.
 **Java references:**
 - `ac.char()` line 244 (of `ac.java`) — server-msg dispatch loop
 - `ac.f()` line 213 → `ac.e()` line 165 — FramebufferUpdate reader
 - `aw.null()` line 459 — FramebufferUpdate header (1 pad + u16 num_rects)
 - `aw.f()` line 468 — per-rectangle header
 - `ByteColorRFBRenderer.if(x,y,w,h)` line 98 — Raw decoder (read w*h bytes,
  blit at offset)
 - `ByteColorRFBRenderer` constructor lines 57–74 — RGB332 → 24bpp LUT
  construction (`DirectColorModel(8, 7, 56, 192)`)
 **Tasks:**
 - [ ] `Framebuffer` struct with `apply_raw(rect, &[u8])`
 - [ ] Static `RGB332_TO_RGBA: [u32; 256]` table generated at compile time via
      `const fn` matching the Java mask layout
 - [ ] Message-dispatch loop with `match` on type byte; only type 0 implemented,
      everything else returns "unhandled type N" error
 - [ ] Send `SetEncodings([0])` + `FramebufferUpdateRequest(full, incremental=false)`
 - [ ] `examples/snapshot.rs` saves first frame as `frame.png`
 **Deliverable:** `cargo run --example snapshot` produces a PNG of whatever the
 KVM is showing — POST screen, BIOS, OS console, whatever. **This is the moment
 the project stops being theoretical.**
 ---
 ## Phase 4 — Hextile + ping + extension messages (`ericrfb/src/codec/hextile.rs`)
 **Goal:** Long-running session that stays connected for hours and renders a
 sequence of frames. Tight not yet supported, but the simpler encodings carry
 us a long way.
 **Java references:**
 - `ByteColorRFBRenderer.int()` line 169 — Hextile decoder. Walk the 16×16 grid;
  for each tile read subencoding byte, then optionally bg/fg colors, optionally
  subrect count + per-subrect coords. Pre-defined palettes don't apply here —
  Hextile uses 1-byte direct color tokens only.
 - `ByteColorRFBRenderer.a(srcX, srcY, x, y, w, h)` line 165 — CopyRect: trivial
  source→dest blit within the framebuffer
 - `aw.b()` line 629 — ping reader (3 bytes ignored + 1 byte payload)
 - `aw.if(int)` line 636 — ping response writer
 **Tasks:**
 - [ ] Hextile decoder, with subrect bit-flag handling matching lines 192–238
 - [ ] CopyRect handler with overlap-safe `copy_within` semantics
 - [ ] Wire up message types 2 (Bell, log only), 17 (no-op ack), 131 (debug string,
      log), 132 (RFB command, log key=value), 148 (ping → respond), 150
      (bandwidth probe — echo per `aw.do()` line 642)
 - [ ] Type 16 (resize) + type 128 (mode change) trigger framebuffer
      reallocation; emit a `Event::Resize(w, h)` to consumers
 - [ ] `examples/record.rs`: 30-second session, save 1 PNG/sec to `out/`
 **Deliverable:** A folder of timestamped PNGs from a real session showing
 boot/login/whatever activity. Connection survives ≥ 1 hour without dropping
 (verifies ping handling).
 ---
 ## Phase 5 — Tight decoder (`ericrfb/src/codec/tight.rs`)
 **Goal:** Server defaults to Tight when bandwidth matters; without this, full
 desktop refreshes are painfully slow. With Tight, video is fluid.
 **Java references:**
 - `ByteColorRFBRenderer.a(x,y,w,h)` line 244 → `a(... null, 0, 0, 0)` line 324
  — Tight dispatcher. Read control byte `n13`. Top 4 bits = stream-reset flags
  + stream-id; bottom 4 bits = subencoding type.
 - Subencoding 8 (line 348) — fill rect with 1-byte color
 - Subencoding 15 (line 351) — fill rect with palette-indexed color (1-byte
  palette selector 1–4 → palettes `C/x/L/I`, then 1-byte index)
 - Subencodings 0–7 (line 380) — zlib-compressed pixel data, optional palette
  filter (filter id 1 = palette mode, 2-color sub-palette from `C/x/L/I`)
 - Subencodings 10–13 (line 432) — reduced bit-depth packed (1/2/4 bpp)
 - `aw.int()` is reused for compressed-stream length (line 297, 457)
 - `case()` at line 691 of the renderer — the four hardcoded sub-palettes,
  ported verbatim
 **Tasks:**
 - [ ] `ZlibStreams { streams: [Option<Decompress>; 4] }` with reset-on-flag
      logic matching lines 336–341
 - [ ] Subencoding 8 (single-color fill)
 - [ ] Subencoding 15 (palette-indexed fill)
 - [ ] Subencoding 0–7 with optional filter byte: copy raw, palette-filtered
      (1-bit packed when palette size = 2)
 - [ ] Subencoding 10–13: bit-unpacking via the predefined LUTs
      (`ByteColorRFBRenderer.if()` at line 580 is the reference)
 - [ ] Constants module with `PALETTE_2`, `PALETTE_4`, `PALETTE_GRAY16`,
      `PALETTE_COLOR16` ported from lines 691–735
 **Deliverable:** SetEncodings advertises `[7, 5, 1, 0, -250]`. The example from
 Phase 4 runs at recognizable framerate. Bandwidth on tcpdump drops by ≥5× vs.
 Phase 4. Visual diff between Tight-decoded and Raw-snapshot frames is byte-
 identical for static screens.
 ---
 ## Phase 6 — Input: keyboard and mouse (`ericrfb/src/input.rs`)
 **Goal:** Send pointer events and keystrokes to the OmniView so the console is
 actually usable.
 **Java references:**
 - `aw.a(boolean, int, int, int, int, int)` line 612 — PointerEvent writer.
  Payload: `[5, button_mask, x_u16, y_u16]`. With `bl=true`, byte 0 becomes 147
  for "exclusive/relative" mode — ignore for v1.
 - `MouseHandlerAbsolute.java` — confirms button-mask bit layout matches RFB
  (bit 0 = left, bit 1 = middle, bit 2 = right, bit 3/4 = wheel up/down)
 - `KeyEventHandler.java` + `nn.pp.rckbd.*` — the keyboard handler is more
  involved than the 2-byte `aw.a(byte)` writer suggests. Read `KeyEventHandler`
  to understand the multi-byte key sequences (HID-style, with separate
  press/release bytes per the `KeyDef.java` model).
 - `KbdLayout_104pc.java` — US layout scancode tables, used as default
 - `KbdMapping_en.java` (in rcsoftkbd) — alternate mapping path
 **Tasks:**
 - [ ] `PointerEvent { mask: u8, x: u16, y: u16 }` writer
 - [ ] Browser-side: capture `mousemove`/`mousedown`/`mouseup` → WS frames
 - [ ] Initial keyboard: send raw scancodes via msg type 4 with the 104pc layout
      table verbatim from `KbdLayout_104pc.java`
 - [ ] Browser-side: `keydown`/`keyup` → JavaScript `KeyboardEvent.code` →
      lookup → scancode → WS frame
 - [ ] CtrlAltDel button in UI sends the hotkey sequence from the HTML param
      `HOTKEYCODE_0` (`"36 f0 37 f0 4e "` = Ctrl down, Alt down, Del down,
      Del up, Alt up, Ctrl up)
 **Deliverable:** Type into BIOS, click in OS installer. The OmniView is
 genuinely usable.
 ---
 ## Phase 7 — Proxy daemon (`crates/ericrfb-proxy`)
 **Goal:** Long-running tokio service that holds a session per browser
 connection. HTTP login flow extracts the APPLET_ID; WebSocket upgrade hands off
 to the protocol pump.
 **Java references:**
 - `RemoteConsoleApplet.if(boolean)` line 312 of `RemoteConsoleApplet.java` —
  shows where `APPLET_ID`, `PORT`, `HOST`, `PROTOCOL_VERSION` are pulled from
  HTML `<param>`. Replicate by HTTP GET-ing `/title_app.asp` (or
  whatever the login flow lands on) and parsing the params from the returned
  HTML.
 - The login HTTP flow itself is **not in the jar** — it's web UI. Capture it
  with browser DevTools' Network tab.
 **Tasks:**
 - [ ] `axum` server: `POST /login` proxies credentials to OmniView, scrapes
      cookies, reads `/title_app.asp`, extracts `APPLET_ID` and other params
 - [ ] `GET /ws/console` upgrades to WebSocket, opens TCP to OmniView, runs
      handshake, then runs a bidirectional pump:
      - OmniView → decoder → RGBA blit messages → WS
      - WS → input event → PointerEvent/KeyEvent → OmniView
 - [ ] Static-files handler serving the built Vite frontend from `dist/`
 - [ ] Configurable via `config.toml`: bind addr, OmniView host, Step CA cert
      paths for mTLS-protecting the proxy itself
 - [ ] systemd quadlet manifest for Podman deployment on whichever homelab host
      cichlid eventually places it
 **Deliverable:** `podman run blekin`, navigate to its URL, log in,
 see the OmniView KVM in a browser tab. Works on any machine on the wireguard
 mesh, no Java anywhere.
 ---
 ## Phase 8 — Frontend (`crates/ericrfb-frontend`)
 **Goal:** Minimal, fast canvas-based renderer matching your stack preferences
 (Vite, React, SWC, TS).
 **No Java references** — the frontend is pure WS-protocol consumer.
 **Tasks:**
 - [ ] `Console.tsx`: `<canvas>` sized to framebuffer dimensions; resize handler
      reallocates on `Event::Resize`
 - [ ] `decoder.ts`: receive WS messages, dispatch on tag:
      - `blit`: `ctx.putImageData(new ImageData(rgba, w, h), x, y)`
      - `copy`: `ctx.drawImage(canvas, srcX, srcY, w, h, x, y, w, h)`
      - `resize`: reallocate canvas
      - `ping`: ignored (handled in proxy)
 - [ ] `input.ts`: pointer + keyboard event capture, send as binary WS frames
 - [ ] Toolbar: CtrlAltDel, full-screen, mouse-mode toggle
 - [ ] Light/dark themes matching your other tools' aesthetic
 **Deliverable:** A polished console UI that doesn't look like a 2005 Java
 applet.
 ---
 ## Phase 9 — Optional: encoding 9 (IIP) and encoding 10
 **Goal:** Performance parity with the original Java applet, only worth doing if
 encoding 7 (Tight) doesn't cut it in practice.
 **Java references:**
 - `ByteColorRFBRenderer.do()` line 248 — encoding 9 dispatcher
 - `ByteColorRFBRenderer.if(...)` line 490 + line 580 — the per-tile delta
  application using the `t[]` cache
 - `t.java` — the per-tile state class. Read this in full; it's stateful across
  rectangles in a way the other encodings aren't.
 - `ByteColorRFBRenderer.for(x,y,w,h)` line 109 — encoding 10 (Raw with tile
  interleave); much simpler than encoding 9
 **Approach:**
 - [ ] Port `t.java` first as `tile_cache.rs`
 - [ ] Encoding 10 is a quick win — basically Raw with a 16×16 deinterleave loop
 - [ ] Encoding 9 needs the cache plumbed end-to-end. Get a known-good capture
      from a real Java session as ground truth. Compare frame-by-frame to
      validate.
 **Deliverable:** Bandwidth and latency matching the original applet. May never
 be needed.
 ---
 ## Phase 10 — Polish
 - [ ] Virtual media (the Floppy/CD-ROM image redirection in the Belkin UI) —
      separate sub-protocol, not in `ac.java`. Probably documented in another
      `aj`/`ac` sibling class. Defer until everything else works.
 - [ ] Reconnection logic: the OmniView drops sessions on reboot; reconnect with
      backoff
 - [ ] Multi-port switching: the OmniView fronts an Avocent KVM — the `port_id`
      field in the ServerInit selects between attached HP servers
 - [ ] mTLS between proxy and browser using your Step CA
 - [ ] Quantum-safe TLS for the proxy's frontend listener (matches your
      preferences); the OmniView side stays plain TCP because the device can't
      do anything modern
 ---
 ## Risk register
 | Risk | Likelihood | Mitigation |
 |------|------------|------------|
 | Encoding 9 needed for usable framerates | Low | SetEncodings doesn't advertise 9 unless user picks "advanced" mode in `RemoteConsoleApplet.if(d2)` line 423; default `[255, 7, -250]` works fine |
 | Keyboard wire format more complex than `aw.a(byte)` suggests | Medium | `KeyEventHandler.java` is small; read it before Phase 6 |
 | HTTP login flow has CSRF / session-binding quirks | Medium | Capture with DevTools first; any irregularities are scriptable |
 | Varint vs u16 confusion in `aw` | High during development | Strict types on `proto.rs` primitives; never use raw integers |
 | Zlib stream desync from dropped/skipped rectangles | High if architecture wrong | Decoder owns the stream; consumers can drop output but never input |
 ## Success criteria
 A working v1 ships when:
 1. Browser tab on any device on the wireguard mesh shows the live OmniView KVM
 2. Mouse and keyboard work for BIOS, OS installer, and running OS
 3. Connection survives ≥ 8 hours uninterrupted
 4. No Java anywhere in the stack
 5. Source on git.lair.cafe under a permissive license, with a README that
   names the Peppercon e-RIC heritage so the next person searching for this
   has a chance of finding it