Files
alknet/docs/architecture/crates/http/overview.md
glm-5.2 125cb49cc4 docs(http): defer h3/WebTransport (ADR-044); browsers use WebSocket for v1
Working through the WebTransport implementation path surfaced a scope
question distinct from the hedging-as-deferral anti-pattern ADR-038 was
written to correct. Three findings drove the re-evaluation:

1. The browser bidirectional call-protocol path doesn't require
   WebTransport — WebSocket is full-duplex, EventEnvelope fits a WS
   binary message boundary cleanly, and the Dispatcher is stream-
   agnostic (ADR-012). What WebTransport gives over WebSocket (native
   multi-stream multiplexing, the ALPN-as-stream substrate) benefits the
   proxy use case, not the call protocol.
2. WebTransport is a draft standard (-07, not RFC) on an experimental
   Rust dependency stack (wtransport/h3 both self-describe as not
   production-ready). Either choice puts a draft protocol on the
   security surface of the first release.
3. The ALPN-stream-proxy (ADR-040) is speculative — its WASM parser
   consumers (browser SSH/SFTP/git clients) don't exist yet, and the
   downstream crates WebTransport deferral blocks (SSH, git, SFTP)
   expose their ALPNs natively over QUIC regardless.

This is a scope decision (per ADR-009: a decision that 'genuinely
doesn't need to be made yet because the use case isn't concrete'), not
hedging. The reversal trigger is concrete: a real deployment needing
the ALPN-stream-proxy.

ADR-038 is superseded (its anti-pattern correction stands; its specific
'h3 in scope now' decision is reversed). ADR-040 and ADR-043 are
parked, not superseded — their designs revive unchanged when WebTransport
revives, with §2 (bidirectionality) and §3 (no-PeerId overlay) of ADR-043
transferring to WebSocket for v1.

ADR-044 §5 also states the 'browser is not a peer' rationale that
ADR-034 §4 closed without arguing: peer = addressable node in the
call-protocol peer graph (stable PeerId, PeerRef::Specific-reachable,
identity stable across reconnects), not 'any endpoint that exchanges
calls during a live session.' A browser is the second but not the first
(no stable crypto identity of its own, ephemeral, not addressable from
other nodes). ADR-034 §4 and Assumption 2 are amended by reference.

The wtransport-vs-hyperium dependency question is recorded (not
resolved — WebTransport is deferred) in ADR-044 §'Research note' and
webtransport.md so the revival doesn't re-derive it: wtransport probably
isn't the right choice (axum-bridge friction — it owns its own HTTP
serving path); the hyperium stack (h3 + h3-quinn + h3-webtransport) fits
the axum integration better but its server-side WebTransport API needs
verification before commitment.

Reviewed by architecture-review subagent; all critical cross-reference
issues (ADR-034 §5 stale 'in scope' assertion, ADR-036 Context listing
h3 as implemented, webtransport.md Design Decisions table) resolved.
2026-06-30 05:55:55 +00:00

17 KiB

status, last_updated
status last_updated
draft 2026-06-30

alknet-http — Overview

The HTTP interface crate: serves inbound HTTP on standard ALPNs (with WebSocket upgrade for browser bidirectional access) and hosts the HTTP-backed call-protocol adapters. This document covers the crate's two roles, its dependency edges, and the adapter location map. Component details are in the sibling documents.

What

alknet-http is the HTTP protocol handler for the ALPN-as-service architecture. It serves two roles in one crate:

  1. HTTP server — a ProtocolHandler (HttpAdapter) that accepts HTTP/2 and HTTP/1.1 connections on the standard IANA ALPNs (h2, http/1.1), plus WebSocket upgrade (for browser bidirectional access to the call protocol). It serves REST APIs, the to_openapi/to_mcp projections of local call-protocol operations, the /healthz operational endpoint, and the decoy surface for stealth mode. HTTP/3 + WebTransport (h3 ALPN) is deferred per ADR-044; the deferred handler design is at webtransport.md.
  2. HTTP client host — the home of the HTTP-transport-backed call adapters: from_openapi (import external HTTP APIs as call operations, using reqwest for outbound calls) and from_mcp (import remote MCP tools over streamable HTTP, using reqwest). The reverse projections to_openapi (generate an OpenAPI doc from the local registry's External operations) and to_mcp (expose local ops as MCP tools over streamable HTTP, using axum) also live here.

Both directions share the same HTTP dependencies (axum for serving, reqwest for calling out), which is why they live in one crate rather than being split into a server crate and a client crate. See ADR-039 for the full rationale.

Why

The crate's purpose is to be the HTTP interface library for downstream crates that need to expose an HTTP interface. A downstream consumer (the CLI binary, a hub deployment, a browser-facing service) wires HttpAdapter into the HandlerRegistry for the standard HTTP ALPNs and gets a full HTTP surface: REST projection of the call protocol, OpenAPI discovery, MCP tool exposure, and WebSocket for browser bidirectional access to the call protocol. (WebTransport is deferred per ADR-044; the deferred browser-streaming path is at webtransport.md.)

The key architectural insight that shapes the crate: HTTP is both a server surface and a client transport for adapters. The server side serves HTTP to external clients (browsers, curl, axios); the client side makes outbound HTTP calls to external APIs (OpenAI, Anthropic, vast.ai) through the from_openapi/from_mcp forwarding handlers. Both directions share HTTP dependencies and HTTP-specific concerns (TLS, headers, streaming, SSE), so they belong in one crate. See ADR-039 for the colocation decision.

A note on the "from/to" direction model: the from_openapi/to_openapi and from_mcp/to_mcp adapters are inherently directional because OpenAPI and MCP are client/server protocols — one side serves, the other calls. That directionality is a property of those protocols, not of the call protocol itself. The call protocol is bidirectional (see ../call/call-protocol.md §"Bidirectional Calls": both sides can initiate calls). The HTTP/1.1 + HTTP/2 surface inherits HTTP's request/response constraint and projects the call protocol one-directionally (client→server calls only — see http-server.md §"One-directional projection"). WebSocket is the HTTP-family transport that restores the call protocol's native bidirectionality for browsers (ADR-044) — a WS connection is a long-lived full-duplex channel over which either side can send call.requested frames in either direction. WebTransport (h3, deferred) would restore it via native multi-stream multiplexing; WebSocket restores it via framed messages over one connection. The "from/to" naming of the OpenAPI/MCP adapters should not be read as a statement about the call protocol's directionality; it is a statement about OpenAPI's and MCP's directionality.

Dependencies

alknet-http
├── alknet-core     (ProtocolHandler, Connection, AuthContext, IdentityProvider, Capabilities)
├── alknet-call     (OperationAdapter, OperationSpec, Handler, HandlerRegistration,
│                    OperationRegistry, AdapterError, OperationProvenance)
├── axum            (HTTP server — Router, extractors, middleware, WebSocket upgrade)
├── reqwest         (HTTP client — from_openapi/from_mcp forwarding)
├── hyper           (HTTP/1.1 + HTTP/2 framing; axum is built on hyper)
└── rmcp            (MCP streamable HTTP — feature-gated behind `mcp`)

Note: the h3/WebTransport dependency (wtransport or the hyperium h3 stack) is not in the v1 dependency tree — h3/WebTransport is deferred per ADR-044. The h3 feature gate and its dependency are absent from the initial release; the browser bidirectional path uses WebSocket (native axum support, no new dependency). The deferred dependency analysis is recorded in ADR-044 §"Research note (for revival)" and webtransport.md §"Research note".

The alknet-call dependency (ADR-003 Amendment 1)

alknet-http depends on alknet-call. ADR-003's rule is "no handler crate depends on another handler crate," but alknet-call is both a handler (it implements ProtocolHandler on alknet/call) and the protocol-foundation crate that alknet-agent, alknet-napi, and now alknet-http consume. alknet-http depending on alknet-call is "HTTP uses the call protocol types" (OperationSpec, Handler, HandlerRegistration, OperationAdapter), not "HTTP depends on SSH." See ADR-003 Amendment 1.

alknet-call stays lean — it has no reqwest, no axum, no HTTP dependencies. The from_openapi/from_mcp forwarding handlers are opaque Arc<dyn Handler> from the registry's perspective: constructed by alknet_http::from_openapi() at registration time, stored in HandlerRegistration, dispatched by the CallAdapter which doesn't know reqwest is involved.

ALPNs

ALPN Handler Transport Browser?
http/1.1 HttpAdapter HTTP/1.1 over QUIC stream (+ WS upgrade) Yes (WS upgrade for bidirectional)
h2 HttpAdapter HTTP/2 over QUIC stream (+ WS upgrade) Yes (WS upgrade for bidirectional)
h3 — (deferred) HTTP/3 / WebTransport Deferred per ADR-044

These are standard IANA ALPN strings, not alknet/-prefixed. Any HTTP client connects without knowing about alknet — the TLS handshake negotiates h2 or http/1.1 normally, and the HttpAdapter serves HTTP. This is the stealth mapping (ADR-010): clients that don't offer alknet ALPNs get the HTTP handler, just like port scanners in stealth mode. A browser negotiates h2 or http/1.1 and upgrades to WebSocket for the bidirectional call-protocol path (ADR-044).

The HttpAdapter registers for http/1.1 and h2. The endpoint's HandlerRegistry maps each ALPN to the same HttpAdapter instance; the handler branches on connection.remote_alpn() to pick the right framing. The h3 ALPN is not registered in v1 (deferred per ADR-044).

Adapter Location Map

The decomposition principle (settled in client-and-adapters.md): the adapter trait lives where the types live (alknet-call); the adapter implementations live where their transport dependencies live.

alknet-call (lean — no HTTP client, no HTTP server)
├── OperationAdapter trait       (the contract — async, ADR-017 §5)
├── from_call                    (QUIC — discovers remote ops via call protocol)
├── from_jsonschema              (pure parse — caller fetches the doc, passes it in)
└── CallClient                   (outbound connection opener)

alknet-http (owns HTTP server + HTTP client)
├── HttpAdapter                  (axum server — inbound HTTP on h2/http1.1 + WS upgrade)
├── from_openapi                 (parse OpenAPI doc + reqwest forwarding handler)
├── to_openapi                   (generate OpenAPI doc from local registry)
├── from_mcp   (feature-gated)   (import remote MCP tools over streamable HTTP — reqwest)
└── to_mcp     (feature-gated)   (expose local ops as MCP tools over streamable HTTP — axum)

alknet-call never sees the HTTP client. The from_openapi/from_mcp forwarding handlers are opaque Arc<dyn Handler> from the registry's perspective. alknet-call stays lean; alknet-http owns both HTTP directions.

Feature Gates

[features]
default = ["h2", "http1"]   # the HTTP surface (incl. WebSocket upgrade for browsers)
mcp = ["dep:rmcp"]           # from_mcp / to_mcp (streamable HTTP only — ADR-037)
# h3 (HTTP/3 + WebTransport) is deferred per ADR-044 — not in the v1
# feature set. The browser bidirectional path uses WebSocket (native to
# axum, no feature gate). When WebTransport revives, the `h3` feature
# gate returns; see ADR-044 and webtransport.md.
  • h2 + http1 (default): the axum + hyper HTTP/1.1 + HTTP/2 server, including WebSocket upgrade for browser bidirectional access (ADR-044). This is the surface all clients — including browsers, via WS upgrade — use in v1.
  • mcp: the rmcp dependency with streamable HTTP transport features only. Adds from_mcp/to_mcp. See http-mcp.md and ADR-037.

A deployment that only needs the REST surface (no MCP) uses the default features. A browser-facing hub also uses the default features — the browser bidirectional path is WebSocket, native to axum, no h3 feature gate needed. A deployment that wants MCP tool import/export enables mcp.

The No-Env-Vars Invariant

The from_openapi/from_mcp forwarding handlers are the credential injection point for the no-env-vars architecture. The path (from the gap analysis):

vault → assembly layer → Capabilities → HandlerRegistration.capabilities
  → OperationContext.capabilities → from_openapi handler reads
    context.capabilities.get("openai") → injects into HTTP Authorization
    header → reqwest request goes out with vault-derived credential

This makes aisdk's std::env::var("OPENAI_API_KEY") reads unreachable — the assembly layer never calls Default::default() on a provider; it constructs them with vault-derived credentials, or routes HTTP calls through from_openapi operations that carry the credential in Capabilities.

This is a spec-level invariant: no handler reads outbound credentials from any source other than OperationContext.capabilities. The from_openapi/from_mcp implementations in alknet-http are verified against this invariant. See ADR-014 and client-and-adapters.md.

Architecture (component pointers)

  • http-server.md — the HttpAdapter for h2/ http/1.1 (+ WebSocket upgrade): how axum is run over a QUIC bidirectional stream, Bearer auth resolution, the /healthz raw route, stealth decoy, the HTTP-to-call dispatch (ADR-036), and the WebSocket browser bidirectional path (ADR-044).
  • http-adapters.mdfrom_openapi (parse OpenAPI, build forwarding handlers with reqwest) and to_openapi (generate an OpenAPI doc from the registry's External operations). Error fidelity per ADR-023.
  • http-mcp.mdfrom_mcp/to_mcp (feature-gated), streamable HTTP only (ADR-037), the rmcp integration.
  • webtransport.md — the deferred h3 ALPN handler (HTTP/3 + WebTransport). Deferred per ADR-044; kept intact for revival when a concrete ALPN-stream-proxy use case arrives.

Design Decisions

Decision ADR Summary
HTTP-to-call operation mapping ADR-036 Direct path mapping; to_openapi is projection, not router
MCP stdio transport exclusion ADR-037 Streamable HTTP only; stdio is not built (RCE vector)
Defer h3/WebTransport; browsers use WebSocket ADR-044 h3/WebTransport deferred (scope, not hedging); browser bidirectional path uses WebSocket; ADR-038 superseded, ADR-040/043 parked
HTTP server + client host colocated ADR-039 One crate for server + adapters (shared HTTP deps, shared mapping)
HTTP/3 + WebTransport first-class ADR-038 Superseded by ADR-044 (anti-pattern correction stands; specific decision reversed)
WebTransport ALPN-stream-proxy ADR-040 Parked per ADR-044; revives unchanged when WebTransport revives
to_mcp tool-gateway pattern ADR-041 4 fixed gateway tools (search/schema/call/batch), not one tool per operation
to_openapi gateway pattern ADR-042 5 fixed gateway endpoints (search/schema/call/batch/subscribe); per-caller AccessControl-filtered
WebTransport bidirectional ALPN substrate ADR-043 Parked per ADR-044; §2/§3 transfer to WebSocket for v1; §4/§5 revive with WebTransport
alknet-call is protocol-foundation ADR-003 Am. 1 alknet-http depends on alknet-call (types, not peer handler)
Bearer auth via resolve_from_token ADR-004 HTTP handler credential source + resolution (settled)
Stealth mode = HTTP handler on standard ALPNs ADR-010 Decoy for unknown paths (settled)
Adapter-registered ops are Internal ADR-015 from_openapi/from_mcp produce Internal leaves (settled)
OperationAdapter trait is async ADR-017 HTTP adapters implement the async trait (settled)
to_* adapters are projections ADR-017 to_openapi/to_mcp consume the registry, don't produce entries (settled)
Error schema fidelity ADR-023 from_openapi maps HTTP status → HTTP_<status> codes; to_openapi projects back (settled)
Browsers require X.509 ADR-027 h3/WebTransport needs X.509 (settled; applies when WebTransport revives)
Browsers are not alknet peers ADR-034 §4 (amended by ADR-044 §5) Browser over WS/WebTransport = bearer token, no PeerId (settled; rationale in ADR-044 §5)

Open Questions

See open-questions.md for full details.

  • OQ-13 (resolved): Operation path format /{service}/{op} — the HTTP path.
  • OQ-26 (resolved): AdapterError variants — reused by HTTP adapters; #[non_exhaustive] allows extension.
  • OQ-37 (resolved): Browsers are not peers; h3 hub is a mixed-fingerprint PeerEntry.
  • OQ-38 (open, scope): WebTransport relay-as-proxy — does the proxy live in alknet-http or a separate relay crate?
  • OQ-39 (open): to_openapi published-spec versioning — versioning strategy for generated OpenAPI specs.
  • OQ-40 (open): reqwest client config and connection pooling — two-way-door config shape.

References

  • docs/research/alknet-http/phase-0-findings.md — Phase 0 research
  • docs/research/alknet-call-completion/gap-analysis.md — adapter location map, no-env-vars invariant
  • /workspace/@alkdev/operations/src/from_openapi.ts, /workspace/@alkdev/operations/src/from_mcp.ts — TypeScript prior art
  • /workspace/rust-sdk/ — MCP Rust SDK (rmcp); streamable HTTP examples
  • /workspace/wtransport/ — pure-Rust WebTransport reference (read during research; not a dependency — see ADR-044 §"Research note" for why wtransport is probably not the right revival choice)