The runtime_brief_slim feature flag has burned in; the slim runtime brief is now the sole path. - execenv: buildMetaSkillContent / BuildCommentReplyInstructions delegate to the slim assembler unconditionally; delete the legacy verbose brief body and writeBackgroundTaskSafetyInstructions. - Remove the runtime_brief_slim flag and the daemon-bound flag delivery subsystem built solely for it: execenv flag wiring (runtime_config_flag.go, server_snapshot_provider.go), the featureflagdispatch package, the DaemonFeatureFlagSnapshot heartbeat protocol field, and the server/daemon wiring in router.go, handler, daemon.go, main.go, cmd_daemon.go. - Keep the generic server/pkg/featureflag engine (still used by composio_mcp_apps). - Update tests to slim-only expectations and docs/feature-flags.md. Co-authored-by: Eve <eve@multica-ai.local> Co-authored-by: multica-agent <github@multica.ai>
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Feature Flags
Multica ships a framework-level feature flag implementation:
- Backend:
server/pkg/featureflag— Go package. - Frontend:
@multica/core/feature-flags— TypeScript module with React hooks.
Both sides share the same vocabulary (Decision, EvalContext, Rule, PercentRollout) and the same FNV-1a percent bucketing, so a flag evaluated on the server and on the client lands in the same bucket for the same user.
The package is designed so new features can adopt feature flags without writing any infrastructure code — drop a rule into the static config, call Service.IsEnabled / useFlag, done.
Core concepts
[Toggle Point] --query--> [Service / Router] --read--> [Provider / Configuration]
business code static / env / chain
- A Toggle Point is the single
ifin business code. It always calls the Service, never the provider directly. - The Service (
Servicein Go,FeatureFlagServicein TS) is the router. Business code never depends on which provider is behind it. - A Provider is the configuration backend. Today we ship
StaticProvider(in-memory rules),EnvProvider(Go only — env-var override), andChainProvider(composition). A future DB or LaunchDarkly provider plugs in without changing any caller. - A Decision is the structured result:
{ enabled, variant, reason, source }.IsEnabledis the boolean projection,Variantis the raw string. UseDecisionfor diagnostic endpoints.
Four flag categories (Martin Fowler):
| Category | Lifetime | Owner | Example |
|---|---|---|---|
| Release | Days–weeks | Engineering | Hide a half-finished page behind flags_release_v2 |
| Experiment | Hours–weeks | Product / Data | A/B test checkout_algo between control and experiment-v2 |
| Ops | Short or evergreen | SRE | Kill switch billing_disable_invoice_pdf |
| Permission | Years | Product | plan_gate_enterprise_dashboard |
Manage them in the same provider but treat them differently: Release flags get deleted; Ops flags need fast override paths (FF_<KEY> env var); Permission flags use Allow lists; Experiment flags use PercentRollout.
Backend (Go)
Wiring at startup
The server constructs a featureflag.Service once in cmd/server/main.go via the standard helper:
flags, err := featureflag.NewServiceFromEnv(featureflag.WithLogger(slog.Default()))
if err != nil {
slog.Error("feature flag configuration failed to load", "error", err)
os.Exit(1)
}
NewServiceFromEnv reads two env vars — both follow the same MULTICA_*_FILE / FF_* conventions documented in .env.example:
| Env var | Role |
|---|---|
MULTICA_FEATURE_FLAGS_FILE |
Path to the YAML rule set (optional; absent = no static rules). |
FF_<FLAG_KEY> |
Per-flag runtime override. FF_BILLING_NEW_INVOICE_EMAIL=false / 25% / experiment-v2. Beats the YAML, no redeploy. |
The provider chain is EnvProvider → YAML StaticProvider. The server can boot with zero flag config — every IsEnabled call falls back to the caller's default until someone authors a rule.
YAML schema
# /etc/multica/feature-flags.yaml
billing_new_invoice_email:
default: true
checkout_algo:
default: false
variant: experiment-v2
percent:
percent: 25
by: user_id
ops_disable_recommendations:
default: false
allow: ["user-internal-1", "user-internal-2"]
allow_by: user_id
Every field except default is optional. variant is the on-variant — see the multi-arm note below. An empty file is a valid "no flags yet" state. Malformed YAML fails startup the same way DATABASE_URL parse errors do, so misconfig surfaces loudly.
Attaching evaluation context to the request
func middleware(flags *featureflag.Service, next http.Handler) http.Handler {
return http.HandlerFunc(func(w http.ResponseWriter, r *http.Request) {
ec := featureflag.EvalContext{
UserID: currentUserID(r),
WorkspaceID: currentWorkspaceID(r),
Attributes: map[string]string{"plan": currentPlan(r)},
}
ctx := featureflag.WithEvalContext(r.Context(), ec)
next.ServeHTTP(w, r.WithContext(ctx))
})
}
Toggle point in business code
if flags.IsEnabled(ctx, "billing_new_invoice_email", false) {
return s.sendNewInvoiceEmail(ctx, invoice)
}
return s.sendLegacyInvoiceEmail(ctx, invoice)
For multi-arm flags:
switch flags.Variant(ctx, "checkout_algo", "control") {
case "experiment-v2":
return checkoutV2(ctx, order)
case "experiment-v3":
return checkoutV3(ctx, order)
default:
return checkoutControl(ctx, order)
}
Rule.Variant is the on-variant: it is only returned when the rule evaluates to enabled=true (allow hit, percent hit, default-on). When the rule evaluates to disabled (deny hit, percent miss, default-off) the Service returns "off" so callers branching on Variant() cannot route control users into the experiment arm. This is exercised by TestStaticProviderVariantOnlyWhenEnabled and is the same on the TS side.
The Service is nil-safe and missing-key-safe: (*Service)(nil).IsEnabled(ctx, "any", true) returns true. Business code never needs to guard against a missing flag.
Frontend (TypeScript / React)
Mounting once at the root
// apps/web/app/_providers.tsx (or the equivalent root)
import {
FeatureFlagsProvider,
FeatureFlagService,
StaticProvider,
} from "@multica/core/feature-flags";
const service = new FeatureFlagService(
new StaticProvider({
billing_v2_dashboard: { default: false, allow: ["user-internal"] },
checkout_algo: { default: true, variant: "experiment-v2",
percent: { percent: 25 } },
}),
);
export function Providers({ children }: { children: ReactNode }) {
const userId = useCurrentUserId();
return (
<FeatureFlagsProvider service={service} context={{ userId }}>
{children}
</FeatureFlagsProvider>
);
}
When the backend pushes a fresh rule set (via an API response or WebSocket), call service.setProvider(new StaticProvider(remoteRules)) and the whole tree re-evaluates.
Toggle point in a component
import { useFlag, useVariant } from "@multica/core/feature-flags";
function BillingPage() {
const showV2 = useFlag("billing_v2_dashboard", false);
return showV2 ? <BillingV2 /> : <BillingV1 />;
}
function Checkout() {
const variant = useVariant("checkout_algo", "control");
switch (variant) {
case "experiment-v2": return <CheckoutV2 />;
case "experiment-v3": return <CheckoutV3 />;
default: return <CheckoutControl />;
}
}
Outside a FeatureFlagsProvider (Storybook, unit tests, error pages) useFlag / useVariant return the supplied default. You never have to mount the provider just to render a component in isolation.
Security note: never rely on the frontend alone
A frontend feature flag controls what the user sees. It does NOT enforce access. Any API route exposing the same capability MUST evaluate the matching backend flag independently. The two flags can share a key but they live in two Service instances and the backend value is the source of truth.
Best-practice checklist
Adopted from Martin Fowler, ConfigCat and Octopus.
- Naming:
{team}_{area}_{behavior}, e.g.billing_checkout_new_payment_flow. Noenable_/disable_prefixes (redundant). - One flag, one purpose: never repurpose an old flag for a new feature. Add a new flag and delete the old one.
- Plan the death of the flag at birth: open a follow-up issue to remove the flag when the rollout completes. Release flags should live days, not quarters.
- Convention:
Offis the legacy / safe state,Onis the new behavior. Lets CI test "all-off (today)" and "all-on (tomorrow)". - Kill switch fast path: ops-critical flags should be exposed via
EnvProviderso SREs can flip them without a deploy. - Backend protection: anything controlling access goes through the backend Service; the frontend flag is presentation only.
- No secrets in flags: variant values are not Secrets Manager / KMS. Use those for tokens, keys, and passwords.
See docs/design.md and docs/timezone-architecture-rfc.md for prior examples of how this pattern is used across the codebase.