Files
netbird/docs/agent-networks/modules/30-proxy-middleware-framework.md
Maycon Santos 92a66cdd20 [management,proxy,client] 0.74.0 version (#6563)
* [management,proxy] Agent network: per-account LLM gateway (policy, metering, multi-provider) (#6555)

* [agent-network] Shared proto, OpenAPI schema, and generated types

* [agent-network] Management: store, manager, synthesizer, policy engine, provider catalog, HTTP/gRPC API

Adds the account-scoped agent-network module: provider/policy/budget CRUD and
store, the reverse-proxy service synthesizer, policy selection + limit
enforcement, the provider catalog (incl. Vertex AI and AWS Bedrock entries),
and the management HTTP + proxy gRPC surfaces.

* [management] Fix agent-network proxy-peer fan-out on affected-peer recompute

The affected-peers resolver loaded only persisted reverse-proxy services, but
agent-network services are synthesized on demand and never persisted. As a
result the embedded proxy peer was never folded into the affected set when a
client's group changed, so the proxy received no network-map update for a newly
authorised client and rejected its handshake until a full resync (restart).

loadProxyServices now merges the synthesized agent-network services (injected
via a registration hook to avoid an import cycle), so proxy peers learn newly
authorised clients immediately.

* [proxy] Reverse-proxy middleware framework, chain, and request plumbing

The per-target middleware chain (slots, dispatcher, mutation gate, metadata
merger), body capture, access-log terminal sink, and the proxy wiring that
builds + runs chains for synthesized agent-network services.

* [proxy] LLM parsers, pricing, and builtin middlewares (OpenAI, Anthropic, Vertex AI, AWS Bedrock)

Request/response parsers and SSE/event-stream metering, the embedded pricing
table, and the builtin middleware set: request parser, router, policy
limit-check/record, cost meter, guardrail, identity inject, response parser.
Includes the path-routed providers — Google Vertex AI (keyfile:: service-account
OAuth minting) and AWS Bedrock (bearer auth, invoke/converse/streaming, optional
/bedrock prefix) — plus the Models allowlist and unmeterable-publisher deny.

* [proxy] IPv6 in-place apply and TCP accept-loop hardening on netstack listeners

* [agent-network] End-to-end test suite, module docs, and deployment preset

* [agent-network] Fix codespell typos and exclude false positives

- labelgen word pool: vermillion -> vermilion, racoon -> raccoon.
- codespell ignore list: add flate (Go compress/flate package), recordin
  (a test-local identifier), and unparseable (a valid alternative spelling used
  consistently across identifiers + a metadata-value constant).

* [management] Set LastSeen on injected proxy peer in realstack test (MySQL strict-mode)

The injected embedded proxy peer had a PeerStatus with a zero LastSeen, which
serializes to '0000-00-00' and is rejected by MySQL in strict mode (SQLite
tolerates it). Set LastSeen to a valid time so SaveAccount succeeds on both
engines.

* [agent-network] Remove e2e shell-script suite from this branch

The end-to-end shell scripts under scripts/e2e/ are maintained in a separate
testing suite and are not part of this change set.

* [agent-network] Polish module docs: remove internal review scaffolding, fix links, verify diagrams

Strip PR-review framing, commit references, absolute paths, and stale internal
references from the agent-network module docs; fix broken relative links; verify
all diagrams against the current architecture. Remove the internal AI-reviewer
prompt file.

* [management] Refine session expiration handling to support 3-state encoding for SSO deadlines

* [agent-network] Relocate agentnetwork package to internals/modules

Move management/server/agentnetwork (and its catalog/, labelgen/, types/
subpackages) to management/internals/modules/agentnetwork, alongside the
reverse-proxy module, and rewrite all importers. Pure relocation: package names,
the synthesizer + affectedpeers registration hook, and store access (shared
store.Store) are unchanged, so no import cycle is introduced (affectedpeers
still depends only on the agentnetwork/types leaf).

* [agent-network] Co-locate HTTP handlers in the module (RegisterEndpoints)

Move the agent-network HTTP handlers from server/http/handlers/agentnetwork into
the module at internals/modules/agentnetwork/handlers (package handlers) and
rename the entrypoint AddEndpoints -> RegisterEndpoints, matching the
reverse-proxy module convention. Wiring in http/handler.go updated accordingly.

* Update getting started to point to rc when agent network enabled

* Add a reference to a commercial license

* Fix docs localhost link

* Fix docs localhost link

* Add private services domain note

* [management] Add agent-network telemetry metrics (#6561)

Surface agent-network adoption and usage in the self-hosted metrics
worker: distinct accounts, providers, policies, budget rules, accounts
with log collection enabled, and aggregated input/output tokens plus
cost.

Tokens and cost are summed from agent_network_request_usage (the
always-written per-request ledger) so the figures are accurate
regardless of the log-collection toggle and carry no double-counting.
All values come from a handful of indexed aggregate queries run only on
the worker's periodic tick.

Adds store.AgentNetworkMetrics with GetAgentNetworkMetrics on the Store
interface, the SqlStore implementation, and a zero-valued FileStore stub.

* Update NetBird server and proxy image versions to 0.74.0-rc.2

* [management,proxy] Reduce agent-network cognitive complexity (#6566)

Address the SonarCloud quality-gate findings in new agent-network code
by extracting focused helpers. No behavior change.

- synthesizer.go: split buildIdentityInjectConfigJSON into per-shape
  rule builders; extract mergeGuardrail from mergeGuardrails to cut
  nesting depth.
- llm_identity_inject: extract injectionEmitsAnything validation
  predicate from New.
- llm_response_parser/streaming.go: extract applyOpenAIStreamUsage and
  applyAnthropicStreamUsage (via a named anthropicStreamUsage type) and
  simplify the OpenAI scanner loop.
- reverseproxy.go: decompose ServeHTTP into serveRouteError,
  buildTargetContext, serveDirect, serveWithChain, captureRequestForChain,
  serveDeny, newResponseWriter, observeResponse, and forwardUpstream,
  preserving the defer ordering so response observation still reads the
  captured writer before it is released.

* [management] Move agent-network access-log ingest into the agentnetwork module (#6568)

The agent-network access-log ingest path (metaKey wire contract, flatten,
usage derivation, and the dual-write of the usage ledger + settings-gated
full row) lived in the reverseproxy accesslogs manager, even though the
agentnetwork module already owns the rest of that domain — types, read
(ListAccessLogs / GetUsageOverview), the budget-counter writes, and
retention cleanup.

Move it next to the rest: a stateless agentnetwork.IngestAccessLog(ctx,
store, entry) that the reverseproxy SaveAccessLog delegates to when the
entry is agent-network. Removes the agentNetworkTypes import from the
reverseproxy manager. No behavior change; the write/read table separation
is unchanged.

Adds real-store coverage for the disable->enable log-collection toggle
(usage ledger always written, full row gated) plus the metadata parse and
group-dedup helpers, which previously had no dedicated tests.

* Add session view support in the access log

* [management,proxy] Container-based agent-network e2e harness (#6577)

* [e2e] Add container-based agent-network e2e harness (Pillar 1)

Introduce a self-contained, OIDC-free e2e harness that stands up NetBird
in containers, so suites no longer depend on the hand-maintained Tilt
stack or a real IdP.

- harness brings up the combined server (management + signal + relay +
  STUN + embedded IdP) in a single container built from
  combined/Dockerfile.multistage, and mints an admin PAT through the
  unauthenticated /api/setup bootstrap (NB_SETUP_PAT_ENABLED). API access
  goes through the existing shared/management/client/rest typed client.
- the image is built via the docker CLI (BuildKit) so the Dockerfile's
  cache mounts are honored; testcontainers then runs the tagged image.
- everything is behind the `e2e` build tag so normal builds and unit
  tests never pull in testcontainers.

Adds BuildKit cache mounts to combined/Dockerfile.multistage so source
changes recompile incrementally rather than from scratch.

Pillar 1 proven by TestCombinedBootstrap: server builds, boots, mints a
PAT, and the PAT authenticates a real management API call.

* [e2e] Add management-side agent-network scenarios (Pillar 2)

Port the API-driven agent-network scenarios from the bash suites to Go,
sharing one combined server per package run (TestMain) with each test
owning its resource cleanup. Drives the /api/agent-network/* endpoints
through the shared REST client's NewRequest primitive with the generated
api types.

Scenarios:
- provider lifecycle (create/get/list/delete + 404 after delete)
- provider validation (missing api_key, unknown catalog id → 4xx)
- settings collection-toggle round-trip with cluster/subdomain immutability
- policy window floor (reject <60s enabled limit, accept at 60s)
- consumption read endpoint returns an array

All deterministic and dependency-free (dummy provider keys; no upstream
calls), so they run headless in CI.

* [e2e] Add live chat-through-proxy scenario (Pillar 3)

Stand up the full agent-network data path in containers and drive a real
chat-completion through the gateway:

- harness: a shared docker network (combined server reachable by alias),
  a proxy container built from the published reverse-proxy image
  (NB_PROXY_PRIVATE, NB_PROXY_ALLOW_INSECURE, NB_RELAY_TRANSPORT=ws to match
  the combined server's WS-multiplexed relay) with a generated self-signed
  wildcard cert, and a netbird client container that joins via a setup key.
- the combined image, proxy image, and client image default to the
  published rc.2 releases (overridable via NB_E2E_*_IMAGE; a bare local tag
  is built from source instead). Geolocation download is disabled so the
  server starts without external fetches.
- one shared domain is used for the management exposed address, the proxy
  domain, and the agent-network cluster; the proxy token is minted via the
  server CLI (global) to match the manual install.

TestChatCompletionThroughProxy provisions provider+policy+group+setup key,
runs proxy+client, drives an OpenAI chat-completion through the tunnel, and
asserts a 200 plus the ingested access-log row. Requires OPENAI_TOKEN
(skips otherwise). The provider must be created with enabled=true explicitly
— the create default is false despite the API doc.

* [e2e] Run the live chat scenario across a provider matrix

Replace the single-provider chat test with a data-driven matrix that runs
the same scenario through every provider whose credentials are present in
the environment (keys/URLs sourced from ~/.llm-keys locally, Actions
secrets in CI):

- OpenAI (chat), Anthropic (messages), Vercel, OpenRouter, Cloudflare
  (OpenAI-compatible gateways), and Bedrock (path-routed, bearer, via the
  messages shape) — covering both wire shapes and the gateway routing.
- all providers are created enabled with a unique model string so the
  proxy's connect-time snapshot carries them all and model->provider
  routing is unambiguous (provider toggles after connect don't reconcile
  to a connected proxy).
- the client supports both wire shapes (/v1/chat/completions and
  /v1/messages); Cloudflare gets the openai provider segment appended to
  its gateway URL.

Each provider must return 200 through the tunnel and produce an ingested
access-log row. Vertex is intentionally excluded from the uniform matrix:
it needs a bespoke rawPredict request shape rather than the shared
chat/messages path, so it warrants a dedicated scenario.

* [ci] Add manual workflow for the agent-network e2e suite

The e2e suite (build tag `e2e`) stands up the combined server + proxy +
client in Docker and drives live chat-completions, so it is slow and needs
provider credentials. Gate it out of normal CI (it already is, via the
build tag) and run it on demand via workflow_dispatch. Provider scenarios
skip when their secret is unset, so it degrades gracefully.

* [e2e] Add Vertex to the provider matrix; run e2e on ubuntu-latest

Vertex (Anthropic-on-Vertex) doesn't share the chat/messages wire shapes:
the model travels in a rawPredict path and the proxy mints the service
account's OAuth token. Add a Vertex client method that posts
/v1/projects/<project>/locations/<region>/publishers/anthropic/models/<model>:rawPredict
with the Vertex anthropic_version body, and wire it into the matrix as a
path-routed provider (created without a models array). It is keyed off
GOOGLE_VERTEX_SA_BASE64 + GOOGLE_VERTEX_PROJECT (region defaults to
"global", model to a pinned claude snapshot, both overridable).

Also bump the e2e workflow runner to ubuntu-latest and add the Vertex
secrets.

* Add docker/docker and docker/go-connections as direct dependencies in go.mod

* [ci] Trigger agent-network e2e workflow on push to main and pull requests

* [e2e] Fix proxy cert permission denied on Linux CI runners

The proxy bind-mounts a temp dir of self-signed certs. MkdirTemp creates
it 0700 and the key was 0600, which Docker Desktop on macOS ignores but a
non-root proxy container on Linux runners cannot traverse/read, so the
cert watcher failed with "open /certs/tls.crt: permission denied" and the
container exited. Widen the cert dir to 0755 and write the throwaway key
0644 so the proxy uid can read the bind-mounted material.

* [e2e] Build images from source by default instead of pulling rc.2

The agent-network code under test lives in this branch, so the e2e should
exercise it rather than a frozen published release. Flip the harness
default: combined/proxy/client are now built from their in-repo
Dockerfiles (combined/Dockerfile.multistage, proxy/Dockerfile.multistage,
e2e/harness/Dockerfile.client) under local tags. Pulling a published image
stays available by setting NB_E2E_*_IMAGE to a registry reference.

Builds now go through buildx --load so the Dockerfile cache mounts are
honored and the result is loaded for testcontainers. The CI workflow adds
a container-driver builder and a local layer cache (NB_E2E_BUILDX_CACHE)
persisted via actions/cache, which caches the base/apt/dep-download layers
across runs. The Go compile still re-runs each time, as BuildKit mount
caches cannot be exported to the GitHub cache.

* [e2e] Cover real providers in lifecycle + assert real consumption metering

- TestProviderLifecycle now runs per available real provider (create → get →
  list → delete → 404) instead of a single dummy provider, exercising each
  catalog's create and field round-trip. Create is offline, so it stays fast
  and burns no provider quota; falls back to a synthetic OpenAI provider when
  no keys are set.
- TestProvidersMatrix attaches a token limit (high caps, 60s window) to its
  policy, which switches on usage metering, and asserts consumption rows are
  recorded with positive token counts after the live traffic. Consumption is
  account-scoped (keyed by source group / user and window, not per provider),
  so the assertion is aggregate.
- TestProviderValidation gains invalid-upstream and blank-name cases. Create
  validation is uniform across catalogs (no per-provider required-field rules),
  so per-provider rejection cases would be redundant.

* [e2e] Assert session id propagates per provider

Each matrix request now sends a unique session id as the universal
x-session-id header and asserts it round-trips into that provider's
access-log row. This guards the session-grouping contract end to end for
every provider (header extraction runs in llm_request_parser ahead of the
parser-specific body extraction, so it is provider-agnostic).

* [e2e] Drop accidentally committed sync-phases dashboard

netbird-sync-phases.json was swept into the Pillar 1 commit by a broad
git add; it belongs to the unrelated sync-phases metrics work, not this
e2e harness. Remove it from the branch so the PR diff is scoped to the
e2e changes.

* [e2e] Revert accidentally committed sync-phase ingest spec

The netbird_sync_phase measurement spec in metrics ingest was swept into
the Pillar 1 commit; it belongs to the unrelated sync-phases metrics work,
not this e2e harness. Its emission side never landed here, so the spec was
orphaned anyway. Restore ingest/main.go to its origin/main state.

* Fix golint issues

* Fix sonar

* Add access log session test

* Fix access log tests

---------

Co-authored-by: braginini <bangvalo@gmail.com>
Co-authored-by: Zoltan Papp <zoltan.pmail@gmail.com>
2026-07-01 12:45:14 +02:00

24 KiB
Raw Blame History

proxy/middleware-framework — generic plugin system

Risk level: High — every proxied request transits this chain. Budget exhaustion, panic recovery, or chain-close bugs hit the hot path for all targets, not just agent-network ones. Backward-compat impact: Additive at the proxy. The middleware and bodytap packages are new (proxy/internal/middleware/middleware.go:1, proxy/internal/middleware/bodytap/request.go:13); existing proxy targets keep working until a chain is bound to them via Manager.Rebuild.

This module is the framework only — no LLM/agent-network domain knowledge is required, since every example built into it is generic.

Module boundary

This module is the framework only: slots, chains, registry, dispatcher, accumulator, body-tap, output filters. No middleware implementation lives here — those land in proxy/internal/middleware/builtin/* (covered in module 31). The package contract is:

  1. The proxy hands a Manager to its config-apply path. The synth pushes per-path PathTargetBinding lists (proxy/internal/middleware/manager.go:26) into Manager.Rebuild, which resolves each spec via the Registry/Resolver (proxy/internal/middleware/registry.go:81-121) and produces an immutable Chain keyed by serviceID|pathID (proxy/internal/middleware/manager.go:410-412).
  2. The reverse-proxy handler captures the request body via bodytap.CaptureRequest, calls Chain.RunRequest, applies returned mutations (already filtered by chain.applyMutations), forwards to the upstream behind a bodytap.CapturingResponseWriter, then calls Chain.RunResponse and Chain.RunTerminal.
  3. Middlewares are inert plugins that receive a deep-cloned Input and return an Output whose decision/mutations are clamped by the dispatcher's filterOutput (proxy/internal/middleware/dispatcher.go:149-172).

Everything that crosses the framework boundary in either direction is value-typed and deep-copied — middlewares cannot mutate the live request directly, and the framework cannot inadvertently leak middleware-owned slices into the request hot path.

Files

Path Role
proxy/internal/middleware/middleware.go Middleware + Factory interfaces.
proxy/internal/middleware/types.go Slot, FailMode, Decision, all limit constants, Input/Output/Mutations/UpstreamRewrite/AuthHeader value types.
proxy/internal/middleware/spec.go Apply-time Spec (validated wire shape + runtime-injected fields) and Clone.
proxy/internal/middleware/registry.go Registry (factory map, RWMutex) and Resolver (Spec → bound Middleware).
proxy/internal/middleware/manager.go Manager, chainTable reverse index, Rebuild/Invalidate*, async chain close.
proxy/internal/middleware/chain.go Chain.RunRequest/RunResponse/RunTerminal, mutation gating, cloneInputFor.
proxy/internal/middleware/chain_test.go Metadata threading, LIFO response order, rewrite gating, UserGroups propagation, terminal accumulation.
proxy/internal/middleware/dispatcher.go Timeout/panic recovery, fail-mode, error classification, filterOutput.
proxy/internal/middleware/decision.go RenderDenyResponse, deny-code regex, status clamp.
proxy/internal/middleware/headerpolicy.go Compile-in header denylist + FilterHeaderMutations.
proxy/internal/middleware/bodypolicy.go ValidateBodyReplace / ApplyBodyReplace smuggling guards.
proxy/internal/middleware/keys.go Metadata key namespace constants.
proxy/internal/middleware/metadata.go Accumulator — allowlist, per-mw/per-request byte caps, redaction.
proxy/internal/middleware/metrics.go OTel instrument bundle (proxy.middleware.*).
proxy/internal/middleware/redaction.go Scan — PEM/JWT/AWS/bearer/Luhn-validated CC patterns.
proxy/internal/middleware/bodytap/request.go Capture + replay reader, Budget semaphore, bypass reason codes.
proxy/internal/middleware/bodytap/response.go CapturingResponseWriter (tee with PassthroughWriter for Flusher/Hijacker preservation).

Slot model

Three slots, declared per-middleware exactly once (proxy/internal/middleware/types.go:27-41):

  • SlotOnRequest (Slot=1) — runs before the upstream call, in registration order. May DecisionDeny, may emit Mutations (header add/remove, body replace, UpstreamRewrite) when both Spec.CanMutate and Middleware.MutationsSupported() are true. May emit metadata. Each middleware in the slot sees metadata that earlier ones in the same slot just emitted (proxy/internal/middleware/chain.go:144-178) — this is how the framework gives middlewares an intra-slot side channel without a global bag.
  • SlotOnResponse (Slot=2) — runs after the upstream returns, in reverse registration order. Cannot deny (clamped in dispatcher.filterOutput, proxy/internal/middleware/dispatcher.go:153-157). May still mutate response headers in principle, but the current chain only forwards RewriteUpstream from on_request, so on_response mutations are observe-only in practice. Threads the same per-slot metadata view as on_request.
  • SlotTerminal (Slot=3) — runs after every on_response middleware has emitted, in registration order. Sees the full accumulated bag plus prior terminal emissions (chain.go:221-245). Cannot deny, cannot mutate (dispatcher.go:168-170). Designed for sinks (access log, metrics push, audit emitter).

Splitting a feature across slots (e.g. "parse on the way out, ship on terminal") is the explicit architectural choice — types.go:7-15 and types.go:22-25 make it clear no middleware participates in more than one slot.

Architecture & flow

Chain dispatch

sequenceDiagram
    autonumber
    participant H as proxy HTTP handler
    participant BT as bodytap.CaptureRequest
    participant CH as Chain
    participant DI as Dispatcher
    participant MW as Middleware (per slot)
    participant US as Upstream
    participant CW as CapturingResponseWriter

    H->>BT: CaptureRequest(r, cfg, budget)
    BT-->>H: body[], truncated, release()
    H->>CH: RunRequest(ctx, r, Input, Accumulator)
    loop on_request, registration order
        CH->>CH: cloneInputFor(in, OnRequest)
        CH->>DI: Invoke(ctx, spec, mw, call)
        DI->>MW: mw.Invoke(callCtx, in)
        MW-->>DI: Output{decision, metadata, mutations?}
        DI->>DI: filterOutput (clamp deny, gate mutations)
        DI-->>CH: filtered Output
        CH->>CH: Accumulator.Emit (allowlist + caps + redact)
        alt DecisionDeny
            CH-->>H: denied, merged, rewrite
        else allow
            CH->>CH: applyMutations(r, m) and capture rewrite
        end
    end
    CH-->>H: nil, merged, rewrite
    H->>US: ProxyRequest (with rewrite/mutations applied)
    US-->>CW: bytes (streamed, tee'd into cap-bounded buf)
    CW-->>H: passthrough complete
    H->>CH: RunResponse(ctx, Input{RespBody:CW.Body(),...}, acc)
    loop on_response, REVERSE order (LIFO)
        CH->>DI: Invoke (same wrappers)
    end
    H->>CH: RunTerminal(ctx, Input{Metadata:full bag}, acc)
    H->>BT: release() + CW.Release()

Body-tap mechanics (request + response)

flowchart LR
    subgraph req[Request capture — bodytap.CaptureRequest]
        R0[r.Body] --> R1{cfg.MaxRequestBytes > 0?\nUpgrade absent?\nContent-Type allowed?\nCL <= cap?}
        R1 -- no --> R2[bypass = reason\nbody = nil\nr.Body untouched]
        R1 -- yes --> R3[Budget.Acquire(cap)]
        R3 -- denied --> R4[bypass=BypassBudget]
        R3 -- ok --> R5[io.LimitReader(r.Body, cap+1)\nio.ReadAll]
        R5 --> R6{len > cap?}
        R6 -- truncated --> R7[viewable = buf[:cap]\nr.Body = replayReadCloser{buf, tail}]
        R6 -- whole --> R8[r.Body = NopCloser(bytes.Reader(buf))\nclose original]
        R7 --> R9[(release captured\nbudget on req end)]
        R8 --> R9
    end

    subgraph resp[Response capture — CapturingResponseWriter]
        W0[client] -.-> CW[Write(p)]
        CW --> P1[PassthroughWriter.Write(p)\n— bytes leave to client first]
        P1 --> P2{!stopped?}
        P2 -- yes --> P3{remaining = cap - buf.Len()}
        P3 --> P4[buf.Write(p[:take])\nset truncated if take<n]
        P2 -- no --> P5[silent drop into the tee\n(client write already done)]
    end

The body-tap is the highest-leak-risk surface in this module; three details matter:

  1. Request capture is "read-and-replay", not "read-and-forward". CaptureRequest always swaps r.Body for either a bytes.Reader (whole body fit) or a replayReadCloser that replays the captured prefix then drains the remaining stream from the original body (bodytap/request.go:178-201). This means the upstream still sees the full body even when the tap truncates. The original r.Body is not closed in the truncated branch — replayReadCloser.Close() only closes the tail (bodytap/request.go:199-201), which is the same reader, so close once on request end is correct, but reviewers should confirm the upstream proxy always reads to EOF (otherwise the tail is leaked).
  2. Response capture is a write-through tee. CapturingResponseWriter.Write forwards to the underlying writer first (bodytap/response.go:116-117), then tees into buf under its own mutex. Client never blocks on the tee. Flusher/Hijacker are preserved via the embedded responsewriter.PassthroughWriter. SSE/chunked streams flow through untouched; middlewares only see the bounded prefix.
  3. Budget is a single shared semaphore. Manager constructs one bodytap.Budget at startup (manager.go:138-144, default 256 MiB from bodytap/request.go:39). Every capture pre-acquires its full MaxRequestBytes / MaxResponseBytes from the budget regardless of actual body size; that prevents a flood of small captures from collectively exceeding the cap, but it also means a misconfigured MaxRequestBytes = 1 MiB with 256 concurrent requests already exhausts the default budget. Reviewers should sanity-check the operator-facing defaults that ship with synth-service.

The framework explicitly aborts capture (and increments proxy.middleware.capture_bypass_total) before reading the first byte when Upgrade/Connection: upgrade is set (bodytap/request.go:120-125), when the content-type isn't in the allowlist (bodytap/request.go:126-128), or when the advertised Content-Length already exceeds the cap (bodytap/request.go:131-133). This is the right place to make sure WebSocket upgrades and large file uploads never reach the buffer.

Public contracts

  • Middleware interface (middleware.go:14-36): ID(), Version(), Slot(), AcceptedContentTypes(), MetadataKeys(), MutationsSupported(), Invoke(ctx, *Input) (*Output, error), Close(). MetadataKeys() is the closed set the middleware is allowed to emit — the accumulator drops anything outside it (metadata.go:71-75). Close must be idempotent (called even when Invoke was never reached).
  • Factory interface (middleware.go:44-47): ID(), New(rawConfig []byte) (Middleware, error). RawConfig is opaque JSON bytes on the wire (spec.go:6-12); each factory owns its own typed config.
  • Decision type (types.go:59-69): Allow=0, Deny=1, Passthrough=2. Default-zero is permissive — important because every middleware that omits Decision gets Allow. Dispatcher clamps Deny to Passthrough outside SlotOnRequest (dispatcher.go:153-157).
  • Mutations (types.go:196-201): HeadersAdd/HeadersRemove (filtered through headerpolicy.go), BodyReplace (gated through bodypolicy.go), and RewriteUpstream. RewriteUpstream is last-write-wins within the on_request slot (chain.go:170-172, locked down by TestChain_RunRequest_LatestRewriteWins).
  • Metadata propagation keys (keys.go): all keys live in a single file and follow ^[a-z][a-z0-9_-]*(\.[a-z0-9_-]*)+$ (metadata.go:8). Framework-injected error tagging uses mw.<id>.error_kind (keys.go:81) so operators can distinguish framework-emitted entries from middleware-emitted ones.

Invariants

  • Per-request context isolation. cloneInputFor deep-copies every mutable field (Headers, RespHeaders, Metadata, Body, RespBody, UserGroups, UserGroupNames) before each invocation (chain.go:286-308). A misbehaving middleware that mutates in.Headers only corrupts its own copy.
  • Body-tap bounded by capture limit. Request side uses io.LimitReader(r.Body, limit+1) (bodytap/request.go:152) — the +1 is how the code detects truncation (bodytap/request.go:160); the surfaced buffer is sliced back down to limit. Response side stops teeing once buf.Len() >= cap (bodytap/response.go:121-133). Neither side can grow the buffer past the configured cap.
  • Headers/body redaction order. Accumulator runs Scan(value) before counting cost (metadata.go:81-82), so the byte budgets are computed against post-redaction sizes. Scan order is PEM → JWT → AWS key → bearer → Luhn-validated CC (redaction.go:25-51) — the comment block in redaction.go:8-13 is explicit that this is best-effort, not DLP.
  • No middleware can starve the chain. Every invocation runs inside context.WithTimeout(ctx, clampTimeout(spec.Timeout)) in a separate goroutine (dispatcher.go:51-94), with the deadline race-selected against the result channel. A blocked middleware fires the timeout path, gets fail-mode'd, and IncError(kind=timeout). Timeouts are clamped to [10ms, 5s] (types.go:80-86, dispatcher.go:174-185).
  • Panic recovery. recover() captures the panic, logs only the type + a 4 KiB stack prefix (no panic value — avoids leaking secrets the middleware was processing), and produces a panicError that flows through fail-mode (dispatcher.go:64-76).
  • Chain immutability + atomic swap. chainTable is cloned on every Rebuild/Invalidate* and swapped via atomic.Pointer (manager.go:44-69, manager.go:221-300). Readers (ChainFor) are lock-free; writers serialise on writeMu. The retired chain is Close-d in a background goroutine bounded by chainCloseTimeout = 2 * MaxTimeout (manager.go:21-22, manager.go:326-346), so in-flight invocations finish on the old chain after the swap.

Things to scrutinize

Correctness

  • Chain ordering deterministic from synth output? Manager.buildChain iterates b.Specs in slice order and appends to bound (manager.go:366-391); NewChain then partitions by slot but preserves slice order within each slot (chain.go:50-60). So order on the wire = order observed at runtime. Synth must therefore emit specs in the intended execution order — there is no per-spec Priority field. Worth flagging.
  • Decision short-circuit semantics. RunRequest returns immediately on DecisionDeny (chain.go:164-167) with the metadata accumulated so far plus the denied.Metadata. Callers that ignore merged on deny will lose framework-injected mw.<id>.error_kind entries. The proxy runtime is the only caller; confirm it always feeds merged into the access log on the deny path as well.
  • UpstreamRewrite AuthHeader bypass (types.go:218-235). The AuthHeader/StripHeaders fields intentionally bypass the header denylist on the basis that the proxy itself rewrites auth. The denylist still blocks middleware-emitted HeadersAdd: Authorization=.... This is a delicate carve-out — review the runtime consumer to confirm only the trusted upstream-build path unpacks AuthHeader, never the generic applyMutations loop.
  • replayReadCloser.Close only closes the tail (bodytap/request.go:199-201). The replay buffer doesn't own a resource, so this is correct, but it conflates "replay finished" with "underlying body closed". If a caller Close()s without reading to EOF, the original body is closed but the captured prefix is lost; harmless for the proxy path (upstream always reads to EOF) but worth a doc-comment.

Security

  • Body-tap memory bounds. Discussed above — bounded by MaxBodyCapBytes = 1 MiB per direction (types.go:77) and the shared Budget (default 256 MiB). The concerning case is the deep-copy in cloneInputFor (chain.go:300-306): every middleware invocation gets its own copy of Body and RespBody. A chain of N middlewares with a 1 MiB body allocates N MiB of transient bytes per request. With MaxMiddlewaresPerChain = 16 (types.go:103) that's up to 16 MiB extra per in-flight request. Worth pricing into the budget model.
  • Header redaction completeness. denyHeaders (headerpolicy.go:5-17) covers the auth/forwarding family and framing (Content-Length, Transfer-Encoding, Trailer). denyHeaderPrefixes covers X-Authenticated-*, X-Forwarded-*, X-Remote-*, X-NetBird-*. Notably absent: Range, If-Match/If-None-Match (mutation could cause cache poisoning), Origin/Referer. Not necessarily wrong, but worth a deliberate decision.
  • Metadata key collisions across middlewares. The accumulator has no cross-middleware uniqueness check; two middlewares with the same key in their allowlist can both emit it, and both copies land in merged (metadata.go:51-99). Downstream consumers must tolerate duplicates. Worth documenting.
  • Deny rendering. RenderDenyResponse only allows codes matching ^[a-z][a-z0-9._-]{0,63}$ (decision.go:9), redacts/truncates message + detail values, caps Details at 8 entries (decision.go:42-50), clamps status to [400,499]\{401} (decision.go:65-73). The deny body type is fixed; middlewares cannot inject arbitrary JSON.

Concurrency

  • Per-request state vs shared state in factories. Each Factory.New is called once per chain build; the returned Middleware instance is shared across all requests for that chain. Invoke must be reentrant. The framework does not enforce this — a buggy middleware that holds per-call state on the struct will silently race. Suggest a // Invoke must be safe for concurrent use doc on the interface.
  • chainTable clone-on-write is correct, but addChain/removeChain mutate the cloned table before the swap (manager.go:71-108), and they're called under writeMu. Readers only ever see the post-swap pointer. Good.
  • Chain.inflight WaitGroup. Run* does Add(1)/Done() (chain.go:142-143, chain.go:194-195, chain.go:225-226); Close waits on it bounded by ctx (chain.go:75-85). One concern: a new RunRequest can Add(1) after Close started waiting if the caller still holds a stale chain pointer. WaitGroup does not panic on this if the count was already > 0 at Wait time, but it does panic if Add happens after Wait returns and another Wait runs. Close is documented one-shot, so single-Wait is fine, but callers must drop the chain reference before calling Close. Worth a code comment near Close.
  • Goroutine leaks. Dispatcher.Invoke spawns one goroutine per call and always writes to a buffered (cap=1) channel (dispatcher.go:62-76), so even if the timeout fires the goroutine completes its send and exits. No leak.
  • closeChainsAsync detaches retired chains into a goroutine (manager.go:326-346). If Manager is never GC'd this is fine, but there's no shutdown hook to wait on outstanding closes. Reviewers should confirm the proxy shutdown path explicitly drains in-flight requests before tearing down Manager, or accept that the last chain-close round may be cut short on exit.

Performance

  • Allocations per request. cloneInputFor allocates new slices for Headers, RespHeaders, Metadata, Body, RespBody, UserGroups, UserGroupNames — once per middleware per request. For a typical 5-middleware chain on a 1 KiB body that's ~10 small slice allocs plus one Body copy each. Not a hot-path crisis, but sync.Pool for the per-call Input would be a natural follow-up.
  • Accumulator allocates a fresh allowSet per Emit call (metadata.go:55-58). One per middleware per slot pass = up to 48 per request. Cheap, but worth noting.
  • Regex cost. Scan runs five regex passes on every accepted metadata value (redaction.go:25-51). Bounded by MaxMetadataValueBytes = 4 KiB so worst case is small.

Observability

  • Per-middleware metrics. proxy.middleware.requests_total{middleware,target_id,outcome} (metrics.go:34-41), duration_ms, invocations_total, errors_total{kind}, metadata_rejected_total{reason}, header_mutation_blocked_total{header}, capture_bypass_total{reason}. Comprehensive surface; operators can alert on errors_total{kind=panic} and errors_total{kind=timeout} separately. Latency histogram is in milliseconds with default OTel buckets — for a 10ms5s timeout range default buckets cover OK, but a custom bucket set centred on 1500ms would resolve the agent-network response-parser tail better.
  • Decision logs. Panic logs (dispatcher.go:69) include request_id, type, and stack but not the panic value (safe). Chain.Close logs middleware-close errors at debug (chain.go:91). applyMutations logs body-replace rejections at warn (chain.go:278). No log on the deny path itself — by design, since the access-log terminal middleware is expected to record outcomes.

Test coverage

Test file Locks down
proxy/internal/middleware/chain_test.go:77 RunRequest threads metadata across on_request middlewares (regression for the "later mw can't see earlier mw's emissions" bug).
chain_test.go:110 RunResponse reverse-order threading.
chain_test.go:142 cost_meter-shaped scenario: response_parser registered after cost_meter still emits before cost_meter sees the bag (guards the cost.skipped=missing_tokens regression).
chain_test.go:178 UpstreamRewrite last-write-wins.
chain_test.go:206 No middleware emits → nil rewrite.
chain_test.go:224 Rewrite filtered when CanMutate=false.
chain_test.go:245 Input.UserGroups propagates verbatim through cloneInputFor.
chain_test.go:304 Terminal middlewares see the full accumulated bag + prior terminal emissions.

Gaps worth raising with the author:

  • No direct test for Dispatcher.Invoke timeout / panic / fail-mode behaviour at the framework level (covered indirectly by built-in tests, but a unit test pinning errors_total{kind=...} labels would be cheap insurance).
  • No test for bodytap.CaptureRequest truncated replay (the upstream-sees-full-body invariant is exactly the kind of thing a regression would silently break).
  • No test for Budget exhaustion behaviour under concurrency.
  • No test for Manager.InvalidateMiddleware + LiveServiceCheck race (the auth-revocation race the comment at manager.go:33-38 calls out is the load-bearing reason for LiveServiceCheck).

Known limitations / explicit non-goals

  • No middleware-to-middleware RPC. Side-channel is metadata only.
  • No streaming body inspection. Middlewares see a bounded prefix; SSE / chunked parsing happens against that prefix in the response middleware.
  • No per-spec priority. Order is registration order in the spec slice.
  • No retry / circuit-breaker on middleware errors. Fail-mode is binary (open/closed) and per-spec.
  • Mutations cannot rewrite the request URL path or query — only RewriteUpstream can change scheme/host (+ optional path replacement, see types.go:218-235).
  • Redaction is best-effort. Explicitly documented in redaction.go:8-13. Not a DLP solution.

Cross-references