Files
multica/server/internal/handler/runtime.go
Naiyuan Qing 21e3cfaa01 Agent runtime status redesign: split presence into availability + last-task (#1794)
* feat(agent-status): add workspace live-tasks endpoint and TaskFailureReason type

Lays the API + type contract for the front-end agent presence cache:

- New `GET /api/active-tasks` returns active (queued/dispatched/running)
  tasks plus failed tasks within the last 2 minutes for the current
  workspace. The 2-minute window powers a UI-side auto-clearing "Failed"
  agent state without back-end pollers.
- `agent_task_queue` has no workspace_id column, so the query JOINs agent;
  `SELECT atq.*` keeps `failure_reason` (migration 055) on the wire.
- Adds `TaskFailureReason` to `AgentTask` so the UI can map the 5 backend
  classifiers (agent_error / timeout / runtime_offline / runtime_recovery
  / manual) to copy without parsing free-text errors.
- New `api.getActiveTasksForWorkspace()` client method; workspace is
  resolved server-side from the X-Workspace-Slug header (no path param,
  matching /api/agents and /api/runtimes conventions).

Includes the joint engineering plan and designer brief that scope the
broader Agent / Runtime status redesign — Phase 0 is this contract plus
the front-end derivation layer landing in the next commit.

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

* feat(agent-status): derive presence/health states with WS sync and desktop IPC bridge

Adds the front-end derivation layer that turns raw server data into the
user-facing 5-state agent / 4-state runtime enums. UI files are
deliberately untouched in this commit — derivation lives behind hooks
(useAgentPresence, useRuntimeHealth) that any component can call with
zero additional network traffic.

Architecture:
- Derivation is pure functions in packages/core/{agents,runtimes}; the
  back-end stays free of UI translation. Agents algorithm: runtime
  offline > recent failed (2-min window) > running > queued > available.
  Runtimes algorithm: status + last_seen_at -> online / recently_lost /
  offline / about_to_gc.
- A single workspace-wide active-tasks query backs all per-agent
  presence reads, eliminating N+1 across hover cards, list rows, and
  pickers. 30-second tick re-renders the hooks so the failed window
  expires even when no underlying data changes.
- WS task lifecycle events (dispatch / completed / failed / cancelled)
  invalidate active-tasks via the prefix dispatcher. completed/failed
  were removed from specificEvents so they go through both the prefix
  invalidate and the existing chat ws.on() handlers. Reconnect refetch
  picks up active-tasks too.
- Desktop bridges window.daemonAPI.onStatusChange directly into the
  runtimes cache via setQueryData, giving the local daemon sub-second
  feedback (vs. 75s server sweep). Bridge is wsId-bound so workspace
  switches automatically rebind the subscription; daemon_id matching
  covers the same-daemon-multiple-providers case.

24 derivation unit tests cover all branches plus null/empty/boundary
inputs (FAILED_WINDOW_MS edges, null last_seen_at, missing
completed_at). Full core suite: 112 tests passing. Typecheck green
across all 8 workspace packages.

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

* feat(agent-status): redesign agent runtime status as two orthogonal dimensions

Splits the conflated 5-state agent presence into two independent axes:

- AgentAvailability (3-state): online / unstable / offline — drives the
  dot indicator everywhere a dot appears. Pure runtime reachability;
  never sticky-red because of a past task outcome.

- LastTaskState (5-state): running / completed / failed / cancelled /
  idle — surfaced as text + icon on focused surfaces (hover card,
  agent detail page, agents list, runtime detail). Never colours the dot.

Major changes:

* Domain layer: AgentPresence union → AgentAvailability + LastTaskState.
  derive-presence split into deriveAgentAvailability + deriveLastTaskState
  + deriveAgentPresenceDetail orchestrator. Tests reorganised into three
  groups (availability invariants, last-task invariants, composition).

* Visual config: presenceConfig (5 entries) → availabilityConfig (3) +
  taskStateConfig (5). availabilityOrder + lastTaskOrder for filter chips.

* Workspace-level presence prefetch: new useWorkspacePresencePrefetch
  hook + WorkspacePresencePrefetch mount component, wired into
  DashboardLayout (web) and WorkspaceRouteLayout (desktop). Hover cards
  render synchronously with no skeleton flash on first hover.

* ActorAvatar hover: flipped default — disableHoverCard removed,
  enableHoverCard added (default false). Opt-in at ~14 decision-moment
  surfaces; pickers / decoration sub-chips stay plain. Status dot
  decoupled (showStatusDot prop) so picker rows can show presence
  without nesting popovers.

* Hover cards: AgentProfileCard simplified — availability dot only,
  Detail link top-right (logs live on the detail page). New
  MemberProfileCard mirrors the structure: name + role + email +
  top-2 owned agents (sorted by 30d run count) with click-through to
  agent detail.

* Agents list: split Status into two columns — availability (3-color
  dot + label) and Last run (task icon + label, optional running
  counts). Two independent filter chip groups (Status + Last run);
  combination acts as intersection ("online + failed" finds broken-
  but-alive agents).

* Other UI surfaces (issue list/board/detail, comments, autopilots,
  projects, runtimes, mention autocomplete, subscribers picker)
  updated to the new dot semantics; status dot now strictly 3-color.

Server changes accompany the client redesign — workspace-wide
agent-task-snapshot endpoint, runtime usage queries, etc. — to feed
the derive layer with the data it needs.

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

* refactor(agent-detail): drop last-task chip from detail header + inspector

The Recent work section on the agent detail page already shows the same
data (with task titles, timestamps, error context) — surfacing
"Completed" / "Failed" / etc. up in the header was redundant chrome.
Detail surfaces now show only the 3-state availability dot.

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

* fix(tables): handle narrow viewports across agents / skills / runtimes

Three table layouts were squeezing content into adjacent cells at
intermediate widths. Each fix is small and targeted:

* runtime-list: the Runtime cell's base name had `shrink-0`, so it
  refused to truncate when its grid column was narrowed under width
  pressure — the name visually overflowed into the Health column
  ("ClaudeOnline" etc). Removed shrink-0, added truncate. The Health
  column was also a fixed 9.5rem reservation for the worst-case
  "Recently lost · 2m 14s ago" copy; switched to minmax(0,1fr) so it
  competes fairly with Runtime.

* skills-page: had a single grid template with no responsive
  breakpoints — all 6 columns were rendered at any width and got
  visually jammed below md. Added a <md template that drops Source +
  Updated; the row markup hides those cells via `hidden md:block` /
  `md:contents`.

* agent-list-item: the new Last run column was reserved at minmax(8rem,
  max-content); on narrow md viewports the 8rem floor pushed the row
  past available width. Changed to minmax(0,max-content) so the cell
  shrinks under pressure (its content already truncates).

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

* refactor(agent-card): hover-only Detail + add Runtime row + breathing room

Three small polish tweaks to the agent hover card:

- Detail link gets `mr-1` + fades in only on card hover (group-hover).
  It was visually flush against the popover edge and competing for
  attention; now it stays out of the way during a quick glance and
  surfaces only when the user is dwelling on the card.

- Runtime row is back, in the meta block (cloud/local icon + runtime
  name). The earlier removal was over-aggressive — knowing where an
  agent runs is part of "who is this agent". The wifi badge stays
  dropped because the availability dot in the header already conveys
  reachability.

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

* feat(runtime): wifi-style health icon (4-state) for runtime list + agent card

Replaces the 6px coloured dot with a wifi-shape icon that carries both
state (Wifi vs WifiOff) and severity (success/warning/muted/destructive).

Mapping:
- online        → Wifi (success)
- recently_lost → WifiHigh (warning) — transient hiccup, fewer bars
- offline       → WifiOff (muted)    — long unreachable
- about_to_gc   → WifiOff (destructive) — sweeper coming soon

Used in two places:

- Runtime list: replaces HealthDot in the dedicated leading-icon column.
  Bumped the column from 0.5rem (dot-sized) to 0.875rem (icon-sized).

- Agent profile card RuntimeRow: derives runtime health from runtime +
  clock (matching the 4-state semantics) and renders HealthIcon next
  to the runtime name. Cloud runtimes always read as online. The
  duplicate signal with the header availability dot is intentional —
  it confirms WHICH runtime is the one currently in the dot's state.

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

---------

Co-authored-by: Claude Opus 4.7 (1M context) <noreply@anthropic.com>
2026-04-28 19:21:13 +08:00

456 lines
14 KiB
Go

package handler
import (
"encoding/json"
"log/slog"
"net/http"
"strconv"
"time"
"github.com/go-chi/chi/v5"
"github.com/jackc/pgx/v5/pgtype"
"github.com/multica-ai/multica/server/pkg/agent"
db "github.com/multica-ai/multica/server/pkg/db/generated"
"github.com/multica-ai/multica/server/pkg/protocol"
)
type AgentRuntimeResponse struct {
ID string `json:"id"`
WorkspaceID string `json:"workspace_id"`
DaemonID *string `json:"daemon_id"`
Name string `json:"name"`
RuntimeMode string `json:"runtime_mode"`
Provider string `json:"provider"`
LaunchHeader string `json:"launch_header"`
Status string `json:"status"`
DeviceInfo string `json:"device_info"`
Metadata any `json:"metadata"`
OwnerID *string `json:"owner_id"`
LastSeenAt *string `json:"last_seen_at"`
CreatedAt string `json:"created_at"`
UpdatedAt string `json:"updated_at"`
}
func runtimeToResponse(rt db.AgentRuntime) AgentRuntimeResponse {
var metadata any
if rt.Metadata != nil {
json.Unmarshal(rt.Metadata, &metadata)
}
if metadata == nil {
metadata = map[string]any{}
}
return AgentRuntimeResponse{
ID: uuidToString(rt.ID),
WorkspaceID: uuidToString(rt.WorkspaceID),
DaemonID: textToPtr(rt.DaemonID),
Name: rt.Name,
RuntimeMode: rt.RuntimeMode,
Provider: rt.Provider,
LaunchHeader: agent.LaunchHeader(rt.Provider),
Status: rt.Status,
DeviceInfo: rt.DeviceInfo,
Metadata: metadata,
OwnerID: uuidToPtr(rt.OwnerID),
LastSeenAt: timestampToPtr(rt.LastSeenAt),
CreatedAt: timestampToString(rt.CreatedAt),
UpdatedAt: timestampToString(rt.UpdatedAt),
}
}
// ---------------------------------------------------------------------------
// Runtime Usage
// ---------------------------------------------------------------------------
type RuntimeUsageResponse struct {
RuntimeID string `json:"runtime_id"`
Date string `json:"date"`
Provider string `json:"provider"`
Model string `json:"model"`
InputTokens int64 `json:"input_tokens"`
OutputTokens int64 `json:"output_tokens"`
CacheReadTokens int64 `json:"cache_read_tokens"`
CacheWriteTokens int64 `json:"cache_write_tokens"`
}
// GetRuntimeUsage returns daily token usage for a runtime, aggregated from
// per-task usage records captured by the daemon. This is scoped to
// Daemon-executed tasks only (i.e. excludes users' local CLI usage of the
// same tool).
func (h *Handler) GetRuntimeUsage(w http.ResponseWriter, r *http.Request) {
runtimeID := chi.URLParam(r, "runtimeId")
runtimeUUID, ok := parseUUIDOrBadRequest(w, runtimeID, "runtime_id")
if !ok {
return
}
rt, err := h.Queries.GetAgentRuntime(r.Context(), runtimeUUID)
if err != nil {
writeError(w, http.StatusNotFound, "runtime not found")
return
}
if _, ok := h.requireWorkspaceMember(w, r, uuidToString(rt.WorkspaceID), "runtime not found"); !ok {
return
}
since := parseSinceParam(r, 90)
rows, err := h.Queries.ListRuntimeUsage(r.Context(), db.ListRuntimeUsageParams{
RuntimeID: rt.ID,
Since: since,
})
if err != nil {
writeError(w, http.StatusInternalServerError, "failed to list usage")
return
}
resp := make([]RuntimeUsageResponse, len(rows))
resolvedRuntimeID := uuidToString(rt.ID)
for i, row := range rows {
resp[i] = RuntimeUsageResponse{
RuntimeID: resolvedRuntimeID,
Date: row.Date.Time.Format("2006-01-02"),
Provider: row.Provider,
Model: row.Model,
InputTokens: row.InputTokens,
OutputTokens: row.OutputTokens,
CacheReadTokens: row.CacheReadTokens,
CacheWriteTokens: row.CacheWriteTokens,
}
}
writeJSON(w, http.StatusOK, resp)
}
// GetRuntimeTaskActivity returns hourly task activity distribution for a runtime.
func (h *Handler) GetRuntimeTaskActivity(w http.ResponseWriter, r *http.Request) {
runtimeID := chi.URLParam(r, "runtimeId")
runtimeUUID, ok := parseUUIDOrBadRequest(w, runtimeID, "runtime_id")
if !ok {
return
}
rt, err := h.Queries.GetAgentRuntime(r.Context(), runtimeUUID)
if err != nil {
writeError(w, http.StatusNotFound, "runtime not found")
return
}
if _, ok := h.requireWorkspaceMember(w, r, uuidToString(rt.WorkspaceID), "runtime not found"); !ok {
return
}
rows, err := h.Queries.GetRuntimeTaskHourlyActivity(r.Context(), rt.ID)
if err != nil {
writeError(w, http.StatusInternalServerError, "failed to get task activity")
return
}
type HourlyActivity struct {
Hour int `json:"hour"`
Count int `json:"count"`
}
resp := make([]HourlyActivity, len(rows))
for i, row := range rows {
resp[i] = HourlyActivity{Hour: int(row.Hour), Count: int(row.Count)}
}
writeJSON(w, http.StatusOK, resp)
}
// RuntimeUsageByAgentResponse is one (agent, model) row of "Cost by agent".
// Model stays on the wire because cost is computed client-side from a model
// pricing table, intentionally not stored server-side so pricing changes
// don't require a back-fill. The client groups by agent_id and sums.
type RuntimeUsageByAgentResponse struct {
AgentID string `json:"agent_id"`
Model string `json:"model"`
InputTokens int64 `json:"input_tokens"`
OutputTokens int64 `json:"output_tokens"`
CacheReadTokens int64 `json:"cache_read_tokens"`
CacheWriteTokens int64 `json:"cache_write_tokens"`
TaskCount int32 `json:"task_count"`
}
// GetRuntimeUsageByAgent returns per-agent token aggregates for a runtime
// since the cutoff window. Drives the runtime-detail "Cost by agent" tab.
func (h *Handler) GetRuntimeUsageByAgent(w http.ResponseWriter, r *http.Request) {
runtimeID := chi.URLParam(r, "runtimeId")
rt, err := h.Queries.GetAgentRuntime(r.Context(), parseUUID(runtimeID))
if err != nil {
writeError(w, http.StatusNotFound, "runtime not found")
return
}
if _, ok := h.requireWorkspaceMember(w, r, uuidToString(rt.WorkspaceID), "runtime not found"); !ok {
return
}
since := parseSinceParam(r, 30)
rows, err := h.Queries.ListRuntimeUsageByAgent(r.Context(), db.ListRuntimeUsageByAgentParams{
RuntimeID: parseUUID(runtimeID),
Since: since,
})
if err != nil {
writeError(w, http.StatusInternalServerError, "failed to list usage by agent")
return
}
resp := make([]RuntimeUsageByAgentResponse, len(rows))
for i, row := range rows {
resp[i] = RuntimeUsageByAgentResponse{
AgentID: uuidToString(row.AgentID),
Model: row.Model,
InputTokens: row.InputTokens,
OutputTokens: row.OutputTokens,
CacheReadTokens: row.CacheReadTokens,
CacheWriteTokens: row.CacheWriteTokens,
TaskCount: row.TaskCount,
}
}
writeJSON(w, http.StatusOK, resp)
}
// RuntimeUsageByHourResponse is one (hour, model) row. Hours with zero
// activity are omitted by the SQL — clients fill the gap to render a
// continuous 0..23 axis. Model is preserved for client-side cost math.
type RuntimeUsageByHourResponse struct {
Hour int `json:"hour"`
Model string `json:"model"`
InputTokens int64 `json:"input_tokens"`
OutputTokens int64 `json:"output_tokens"`
CacheReadTokens int64 `json:"cache_read_tokens"`
CacheWriteTokens int64 `json:"cache_write_tokens"`
TaskCount int32 `json:"task_count"`
}
// GetRuntimeUsageByHour returns hourly (0..23) token aggregates for a
// runtime since the cutoff window. Drives the "By hour" tab.
func (h *Handler) GetRuntimeUsageByHour(w http.ResponseWriter, r *http.Request) {
runtimeID := chi.URLParam(r, "runtimeId")
rt, err := h.Queries.GetAgentRuntime(r.Context(), parseUUID(runtimeID))
if err != nil {
writeError(w, http.StatusNotFound, "runtime not found")
return
}
if _, ok := h.requireWorkspaceMember(w, r, uuidToString(rt.WorkspaceID), "runtime not found"); !ok {
return
}
since := parseSinceParam(r, 30)
rows, err := h.Queries.GetRuntimeUsageByHour(r.Context(), db.GetRuntimeUsageByHourParams{
RuntimeID: parseUUID(runtimeID),
Since: since,
})
if err != nil {
writeError(w, http.StatusInternalServerError, "failed to get usage by hour")
return
}
resp := make([]RuntimeUsageByHourResponse, len(rows))
for i, row := range rows {
resp[i] = RuntimeUsageByHourResponse{
Hour: int(row.Hour),
Model: row.Model,
InputTokens: row.InputTokens,
OutputTokens: row.OutputTokens,
CacheReadTokens: row.CacheReadTokens,
CacheWriteTokens: row.CacheWriteTokens,
TaskCount: row.TaskCount,
}
}
writeJSON(w, http.StatusOK, resp)
}
// GetWorkspaceUsageByDay returns daily token usage aggregated by model for the workspace.
func (h *Handler) GetWorkspaceUsageByDay(w http.ResponseWriter, r *http.Request) {
workspaceID := h.resolveWorkspaceID(r)
since := parseSinceParam(r, 30)
rows, err := h.Queries.GetWorkspaceUsageByDay(r.Context(), db.GetWorkspaceUsageByDayParams{
WorkspaceID: parseUUID(workspaceID),
Since: since,
})
if err != nil {
writeError(w, http.StatusInternalServerError, "failed to get usage")
return
}
type DailyUsageRow struct {
Date string `json:"date"`
Model string `json:"model"`
TotalInputTokens int64 `json:"total_input_tokens"`
TotalOutputTokens int64 `json:"total_output_tokens"`
TotalCacheReadTokens int64 `json:"total_cache_read_tokens"`
TotalCacheWriteTokens int64 `json:"total_cache_write_tokens"`
TaskCount int32 `json:"task_count"`
}
resp := make([]DailyUsageRow, len(rows))
for i, row := range rows {
resp[i] = DailyUsageRow{
Date: row.Date.Time.Format("2006-01-02"),
Model: row.Model,
TotalInputTokens: row.TotalInputTokens,
TotalOutputTokens: row.TotalOutputTokens,
TotalCacheReadTokens: row.TotalCacheReadTokens,
TotalCacheWriteTokens: row.TotalCacheWriteTokens,
TaskCount: row.TaskCount,
}
}
writeJSON(w, http.StatusOK, resp)
}
// GetWorkspaceUsageSummary returns total token usage aggregated by model for the workspace.
func (h *Handler) GetWorkspaceUsageSummary(w http.ResponseWriter, r *http.Request) {
workspaceID := h.resolveWorkspaceID(r)
since := parseSinceParam(r, 30)
rows, err := h.Queries.GetWorkspaceUsageSummary(r.Context(), db.GetWorkspaceUsageSummaryParams{
WorkspaceID: parseUUID(workspaceID),
Since: since,
})
if err != nil {
writeError(w, http.StatusInternalServerError, "failed to get usage summary")
return
}
type UsageSummaryRow struct {
Model string `json:"model"`
TotalInputTokens int64 `json:"total_input_tokens"`
TotalOutputTokens int64 `json:"total_output_tokens"`
TotalCacheReadTokens int64 `json:"total_cache_read_tokens"`
TotalCacheWriteTokens int64 `json:"total_cache_write_tokens"`
TaskCount int32 `json:"task_count"`
}
resp := make([]UsageSummaryRow, len(rows))
for i, row := range rows {
resp[i] = UsageSummaryRow{
Model: row.Model,
TotalInputTokens: row.TotalInputTokens,
TotalOutputTokens: row.TotalOutputTokens,
TotalCacheReadTokens: row.TotalCacheReadTokens,
TotalCacheWriteTokens: row.TotalCacheWriteTokens,
TaskCount: row.TaskCount,
}
}
writeJSON(w, http.StatusOK, resp)
}
// parseSinceParam parses the "days" query parameter and returns a timestamptz.
func parseSinceParam(r *http.Request, defaultDays int) pgtype.Timestamptz {
days := defaultDays
if d := r.URL.Query().Get("days"); d != "" {
if parsed, err := strconv.Atoi(d); err == nil && parsed > 0 && parsed <= 365 {
days = parsed
}
}
t := time.Now().AddDate(0, 0, -days)
return pgtype.Timestamptz{Time: t, Valid: true}
}
func (h *Handler) ListAgentRuntimes(w http.ResponseWriter, r *http.Request) {
workspaceID := h.resolveWorkspaceID(r)
var runtimes []db.AgentRuntime
var err error
if ownerFilter := r.URL.Query().Get("owner"); ownerFilter == "me" {
userID, ok := requireUserID(w, r)
if !ok {
return
}
runtimes, err = h.Queries.ListAgentRuntimesByOwner(r.Context(), db.ListAgentRuntimesByOwnerParams{
WorkspaceID: parseUUID(workspaceID),
OwnerID: parseUUID(userID),
})
} else {
runtimes, err = h.Queries.ListAgentRuntimes(r.Context(), parseUUID(workspaceID))
}
if err != nil {
writeError(w, http.StatusInternalServerError, "failed to list runtimes")
return
}
resp := make([]AgentRuntimeResponse, len(runtimes))
for i, rt := range runtimes {
resp[i] = runtimeToResponse(rt)
}
writeJSON(w, http.StatusOK, resp)
}
// DeleteAgentRuntime deletes a runtime after permission and dependency checks.
func (h *Handler) DeleteAgentRuntime(w http.ResponseWriter, r *http.Request) {
runtimeID := chi.URLParam(r, "runtimeId")
runtimeUUID, ok := parseUUIDOrBadRequest(w, runtimeID, "runtime_id")
if !ok {
return
}
rt, err := h.Queries.GetAgentRuntime(r.Context(), runtimeUUID)
if err != nil {
writeError(w, http.StatusNotFound, "runtime not found")
return
}
wsID := uuidToString(rt.WorkspaceID)
member, ok := h.requireWorkspaceMember(w, r, wsID, "runtime not found")
if !ok {
return
}
// Permission: owner/admin can delete any runtime; members can only delete their own.
userID := uuidToString(member.UserID)
isAdmin := roleAllowed(member.Role, "owner", "admin")
isOwner := rt.OwnerID.Valid && uuidToString(rt.OwnerID) == userID
if !isAdmin && !isOwner {
writeError(w, http.StatusForbidden, "you can only delete your own runtimes")
return
}
// Check if any active (non-archived) agents are bound to this runtime.
activeCount, err := h.Queries.CountActiveAgentsByRuntime(r.Context(), rt.ID)
if err != nil {
writeError(w, http.StatusInternalServerError, "failed to check runtime dependencies")
return
}
if activeCount > 0 {
writeError(w, http.StatusConflict, "cannot delete runtime: it has active agents bound to it. Archive or reassign the agents first.")
return
}
// Remove archived agents so the FK constraint (ON DELETE RESTRICT) won't block deletion.
if err := h.Queries.DeleteArchivedAgentsByRuntime(r.Context(), rt.ID); err != nil {
writeError(w, http.StatusInternalServerError, "failed to clean up archived agents")
return
}
if err := h.Queries.DeleteAgentRuntime(r.Context(), rt.ID); err != nil {
writeError(w, http.StatusInternalServerError, "failed to delete runtime")
return
}
slog.Info("runtime deleted", "runtime_id", uuidToString(rt.ID), "deleted_by", userID)
// Notify frontend to refresh runtime list.
h.publish(protocol.EventDaemonRegister, wsID, "member", userID, map[string]any{
"action": "delete",
})
writeJSON(w, http.StatusOK, map[string]string{"status": "ok"})
}