Vetting/agent/runner.go

// Package agent implements the in-live-image control loop.
//
// Phase 4 scope: after /claim, the agent walks through every stage the
// orchestrator advertises, dispatching on the stage name to a function
// in agent/tests. Each stage posts a /result; the response carries the
// orchestrator's next_state, which the loop uses to pick the next
// stage. Stages the orchestrator owns (SpecValidate, Reporting) resolve
// server-side inside /result so the agent never sees them as "its turn".
//
// Terminal states:
//   - FailedHolding → request hold key, install authorized_keys, wait
//     on heartbeats for a retry_stage directive.
//   - Completed → heartbeat carries cmd=shutdown; agent runs
//     `systemctl poweroff` and exits.
//
// Thermal sidecar runs from the moment the agent claims until ctx
// cancel; it posts a handful of /sys/class/hwmon samples every 5s.
package agent

import (
	"context"
	"encoding/json"
	"fmt"
	"log"
	"net"
	"os"
	"os/exec"
	"path/filepath"
	"strings"
	"sync"
	"sync/atomic"
	"time"

	"vetting/agent/bootstate"
	"vetting/agent/probes"
	"vetting/agent/tests"
	"vetting/internal/spec"
)

// stageCancel holds the cancel func for the in-flight stage ctx so the
// heartbeat loop can fire it when the orchestrator returns
// cmd=cancel_stage. Stored as an atomic.Value so the heartbeat goroutine
// can read without locking; writes happen only on the main loop.
var stageCancel atomic.Value // context.CancelFunc

// Run is the long-lived entry point. It blocks until ctx is cancelled
// or a fatal error makes progress impossible.
func Run(ctx context.Context, p *bootstate.Params) error {
	c := NewClient(p.OrchestratorURL, p.RunID, p.Token, p.TLSCertFPR)
	fwd := newLogForwarder(ctx, c)
	defer fwd.close()

	ip := localIP()
	fwd.info(fmt.Sprintf("agent starting on %s (run=%d mac=%s)", ip, p.RunID, p.MAC))

	if err := callWithBackoff(ctx, "hello", func(ctx context.Context) error {
		return c.Hello(ctx)
	}); err != nil {
		fwd.warn("hello never succeeded: " + err.Error())
	}

	var claim *ClaimResponse
	if err := callWithBackoff(ctx, "claim", func(ctx context.Context) error {
		r, err := c.Claim(ctx, ip)
		if err != nil {
			return err
		}
		claim = r
		return nil
	}); err != nil {
		return err
	}
	fwd.info(fmt.Sprintf("claimed run; stages=%v current_state=%s", claim.Stages, claim.CurrentState))

	mux := NewSensorMux(ctx, c)
	defer mux.Close()

	go thermalSidecar(ctx, mux, fwd)

	hbCh := make(chan HeartbeatResponse, 4)
	go heartbeatLoop(ctx, c, fwd, hbCh)

	// Run every stage the orchestrator advertises. Stages owned by the
	// orchestrator (SpecValidate, Reporting) resolve inside /result and
	// flip next_state forward past themselves, so they simply never match
	// our dispatch table.
	//
	// Start stage comes from claim.CurrentState so a re-claim after an
	// agent crash resumes at the stage the run was parked at, instead of
	// blindly replaying Inventory and letting the orchestrator silently
	// advance past the crashed stage (the Orion OOM bug). A fresh claim
	// naturally lands on InventoryCheck, which maps back to "Inventory".
	nextStage := stageForState(claim.CurrentState)
	if nextStage == "" {
		nextStage = "Inventory"
	}
	if nextStage != "Inventory" {
		fwd.warn(fmt.Sprintf("resuming mid-pipeline at %s (claim current_state=%s) — likely agent restart after crash",
			nextStage, claim.CurrentState))
	}
	for nextStage != "" {
		select {
		case <-ctx.Done():
			return ctx.Err()
		default:
		}
		fwd.info("stage: starting " + nextStage)
		outcome := runStageCancellable(ctx, nextStage, claim, fwd, c, mux, overrideFlags{})
		if outcome.Cancelled {
			fwd.warn("stage cancelled by operator; posting result and exiting")
			_, _ = postResult(ctx, c, nextStage, outcome)
			return powerOffAndReturn(fwd)
		}
		resp, err := postResult(ctx, c, nextStage, outcome)
		if err != nil {
			fwd.error("submit result for " + nextStage + ": " + err.Error())
			return err
		}
		fwd.info(fmt.Sprintf("stage %s → next_state=%s", nextStage, resp.NextState))

		if resp.NextState == "FailedHolding" {
			if err := requestHold(ctx, c, fwd); err != nil {
				return err
			}
			// Park and wait for an override directive.
			return waitForOverride(ctx, c, fwd, mux, hbCh, claim)
		}
		if resp.NextState == "Completed" || resp.NextState == "" {
			fwd.info("pipeline complete")
			<-ctx.Done()
			return ctx.Err()
		}
		nextStage = stageForState(resp.NextState)
		if nextStage == "" {
			// next_state is something we don't map (e.g. SpecValidate — but
			// the orchestrator's /result already resolved it and handed us
			// back a further-along state). Defensive bail so we don't loop.
			fwd.warn("no stage maps to state " + resp.NextState + "; parking")
			<-ctx.Done()
			return ctx.Err()
		}
	}
	<-ctx.Done()
	return ctx.Err()
}

// runStage dispatches on stage name. The Inventory stage is special —
// it runs the inventory probe and passes the result as the /result body
// (the orchestrator persists it as an artifact). Every other stage
// returns a tests.Outcome which postResult marshals generically.
func runStage(ctx context.Context, stage string, claim *ClaimResponse, fwd *logForwarder, c *Client, mux *SensorMux, ovr overrideFlags) stageOutcome {
	fwd.SetStage(stage)
	defer fwd.ClearStage()
	deps := newDeps(ctx, c, fwd, mux, ovr, claim, stage)
	switch stage {
	case "Inventory":
		fwd.info("Inventory: probing host hardware")
		log := probes.Logger{Info: fwd.info, Warn: fwd.warn}
		inv := &spec.Inventory{}
		var subs []tests.SubStepReport
		runSub := func(name string, fn func()) {
			start := time.Now()
			fn()
			subs = append(subs, tests.SubStepReport{
				Name:        name,
				Passed:      true,
				StartedAt:   start,
				CompletedAt: time.Now(),
			})
		}
		runSub("CPU", func() { inv.CPU = probes.CPU(log) })
		runSub("Memory", func() { inv.Memory = probes.Memory(log) })
		runSub("Disks", func() { inv.Disks = probes.Disks(log) })
		runSub("NICs", func() { inv.NICs = probes.NICs(log) })
		runSub("GPUs", func() { inv.GPUs = probes.GPUs(log) })
		runSub("System", func() { inv.System = probes.System(log) })
		runSub("Baseboard", func() { inv.Baseboard = probes.Baseboard(log) })
		runSub("PSU", func() { inv.PSU = probes.PSU(log) })
		runSub("OS", func() { inv.OS = probes.OS(log) })
		summary := inventorySummary(inv)
		fwd.info("Inventory: " + summary)
		return stageOutcome{
			Outcome: tests.Outcome{
				Passed:   true,
				Summary:  summary,
				SubSteps: subs,
			},
			Inventory: inv,
		}
	case "Firmware":
		fwd.info("Firmware: probing firmware versions")
		snaps, warns := probes.Firmware(ctx)
		for _, w := range warns {
			fwd.warn(w)
		}
		summary := firmwareSummary(snaps)
		fwd.info("Firmware: " + summary)
		return stageOutcome{
			Outcome: tests.Outcome{
				Passed:  true,
				Summary: summary,
				Extras: map[string]any{
					"warnings":  warns,
					"snapshots": len(snaps),
				},
			},
			Firmware: snaps,
		}
	case "SMART":
		return stageOutcome{Outcome: tests.SMART(ctx, deps)}
	case "CPUStress":
		return stageOutcome{Outcome: tests.CPUStress(ctx, deps)}
	case "Storage":
		return stageOutcome{Outcome: tests.Storage(ctx, deps)}
	case "Network":
		duration := deps.NetworkKnobs.Duration
		if duration <= 0 {
			duration = 10 * time.Second
		}
		return stageOutcome{Outcome: tests.Network(ctx, deps, tests.NetworkConfig{
			OrchestratorURL: c.BaseURL,
			IperfPort:       claim.IperfPort,
			Duration:        duration,
		})}
	case "Burn":
		return stageOutcome{Outcome: tests.Burn(ctx, deps, tests.BurnConfig{
			OrchestratorURL: c.BaseURL,
			IperfPort:       claim.IperfPort,
		})}
	case "GPU":
		return stageOutcome{Outcome: tests.GPU(ctx, deps)}
	case "PSU":
		return stageOutcome{Outcome: tests.PSU(ctx, deps)}
	}
	return stageOutcome{Outcome: tests.Outcome{
		Passed:  false,
		Message: "unknown stage " + stage,
	}}
}

type stageOutcome struct {
	Outcome   tests.Outcome
	Inventory *spec.Inventory           // only for Inventory stage
	Firmware  []probes.FirmwareSnapshot // only for Firmware stage
	Cancelled bool                      // set when the stage was cut short by operator cancel
}

// runStageCancellable wraps runStage in a per-stage context so the
// heartbeat loop's cancel_stage directive can kill whatever subprocess
// is currently running. If the derived context was cancelled while the
// stage executed, the outcome is rewritten as a cancellation record so
// the orchestrator has something to persist.
func runStageCancellable(parent context.Context, stage string, claim *ClaimResponse, fwd *logForwarder, c *Client, mux *SensorMux, ovr overrideFlags) stageOutcome {
	stageCtx, cancel := context.WithCancel(parent)
	stageCancel.Store(cancel)
	defer func() {
		cancel()
		stageCancel.Store(context.CancelFunc(nil))
	}()
	out := runStage(stageCtx, stage, claim, fwd, c, mux, ovr)
	// If the parent is still live but the stage ctx was cancelled, the
	// operator fired a cancel — mark the outcome so the caller can exit
	// the pipeline cleanly. Plain ctx-cancel on ctx.Done (e.g. shutdown)
	// is handled elsewhere by the main loop's select.
	if parent.Err() == nil && stageCtx.Err() != nil {
		out.Cancelled = true
		out.Outcome.Passed = false
		if out.Outcome.Message == "" {
			out.Outcome.Message = "stage cancelled by operator"
		}
		out.Outcome.Summary = "cancelled"
	}
	return out
}

// powerOffAndReturn shuts the host down after an operator cancel. Same
// best-effort poweroff path as the shutdown heartbeat cmd.
func powerOffAndReturn(fwd *logForwarder) error {
	fwd.info("cancel: powering off host")
	if err := exec.Command("systemctl", "poweroff").Run(); err != nil {
		fwd.warn("systemctl poweroff failed: " + err.Error())
		_ = exec.Command("shutdown", "-h", "now").Run()
	}
	return nil
}

type overrideFlags struct {
	Wipe bool `json:"wipe"`
}

func newDeps(ctx context.Context, c *Client, fwd *logForwarder, mux *SensorMux, ovr overrideFlags, claim *ClaimResponse, stage string) tests.Deps {
	var expected []tests.ExpectedDisk
	for _, e := range claim.ExpectedDisks {
		expected = append(expected, tests.ExpectedDisk{Serial: e.Serial, SizeGB: e.SizeGB})
	}
	return tests.Deps{
		Info:           fwd.info,
		Warn:           fwd.warn,
		Error:          fwd.error,
		OverrideWipe:   ovr.Wipe,
		NonDestructive: claim.NonDestructive,
		ExpectedDisks:  expected,
		StageTimeout:   stageTimeout(claim, stage),
		CPUStressKnobs: tests.CPUStressKnobs{
			CPUPass:  parseDur(claim.StageConfig.CPUStress.CPUPass),
			MemPass:  parseDur(claim.StageConfig.CPUStress.MemPass),
			EDACPoll: parseDur(claim.StageConfig.CPUStress.EDACPoll),
		},
		StorageKnobs: tests.StorageKnobs{
			Mode:    claim.StageConfig.Storage.Mode,
			FioSize: claim.StageConfig.Storage.FioSize,
			FioTime: parseDur(claim.StageConfig.Storage.FioTime),
			FioBS:   claim.StageConfig.Storage.FioBS,
			FioRW:   claim.StageConfig.Storage.FioRW,
			Verify:  claim.StageConfig.Storage.Verify,
		},
		NetworkKnobs: tests.NetworkKnobs{
			Duration: parseDur(claim.StageConfig.Network.Duration),
		},
		BurnKnobs: tests.BurnKnobs{
			Duration:      parseDur(claim.StageConfig.Burn.Duration),
			CPUWorkers:    claim.StageConfig.Burn.CPUWorkers,
			MemPct:        claim.StageConfig.Burn.MemPct,
			FioOnSpare:    claim.StageConfig.Burn.FioOnSpare,
			IperfParallel: claim.StageConfig.Burn.IperfParallel,
		},
		Sensor: func(_ context.Context, samples []tests.Sample) error {
			out := make([]SensorSample, 0, len(samples))
			for _, s := range samples {
				out = append(out, SensorSample{Kind: s.Kind, Key: s.Key, Value: s.Value, Unit: s.Unit})
			}
			mux.Send(out)
			return nil
		},
	}
}

// stageTimeout reads claim.StageConfig.StageTimeouts[stage] and falls
// back to 2 minutes (the pre-Phase-2 default). Malformed entries log and
// fall back — we'd rather run the stage than refuse on a typo.
func stageTimeout(claim *ClaimResponse, stage string) time.Duration {
	if claim == nil || claim.StageConfig.StageTimeouts == nil {
		return 2 * time.Minute
	}
	raw, ok := claim.StageConfig.StageTimeouts[stage]
	if !ok || raw == "" {
		return 2 * time.Minute
	}
	d, err := time.ParseDuration(raw)
	if err != nil || d <= 0 {
		return 2 * time.Minute
	}
	return d
}

// parseDur is the permissive duration parser for the knob wire shape.
// Empty strings / parse failures yield 0 so callers can treat a zero
// value as "use the compile-time default" without a nil-check dance.
func parseDur(s string) time.Duration {
	if s == "" {
		return 0
	}
	d, err := time.ParseDuration(s)
	if err != nil || d < 0 {
		return 0
	}
	return d
}

// postResult marshals stageOutcome for the /result endpoint. The
// Inventory shape is special-cased: it includes the inventory blob so
// the orchestrator can persist it and run server-side spec diff.
func postResult(ctx context.Context, c *Client, stage string, s stageOutcome) (*ResultResponse, error) {
	summary, _ := s.Outcome.MarshalSummary()
	body := map[string]any{
		"stage":  stage,
		"passed": s.Outcome.Passed,
	}
	if len(summary) > 2 {
		body["summary"] = json.RawMessage(summary)
	}
	if s.Outcome.Message != "" {
		body["message"] = s.Outcome.Message
	}
	if s.Inventory != nil {
		body["inventory"] = s.Inventory
	}
	if len(s.Firmware) > 0 {
		body["firmware"] = s.Firmware
	}
	if len(s.Outcome.SubSteps) > 0 {
		wire := make([]SubStepReport, 0, len(s.Outcome.SubSteps))
		for _, ss := range s.Outcome.SubSteps {
			w := SubStepReport{
				Name:    ss.Name,
				Passed:  ss.Passed,
				Skipped: ss.Skipped,
				Summary: ss.SummaryJSON,
			}
			if !ss.StartedAt.IsZero() {
				w.StartedAt = ss.StartedAt.UTC().Format(time.RFC3339Nano)
			}
			if !ss.CompletedAt.IsZero() {
				w.CompletedAt = ss.CompletedAt.UTC().Format(time.RFC3339Nano)
			}
			wire = append(wire, w)
		}
		body["sub_steps"] = wire
	}
	return c.Result(ctx, body)
}

// stageForState maps a RunState string back to the stage executor name.
// Every stage-name is the same as its state except Inventory↔InventoryCheck.
func stageForState(state string) string {
	switch state {
	case "InventoryCheck":
		return "Inventory"
	case "Firmware", "SMART", "CPUStress", "Storage", "Network", "Burn", "GPU", "PSU":
		return state
	}
	// SpecValidate and Reporting are orchestrator-owned; we never see
	// them as next_state because /result resolves past them.
	return ""
}

// waitForOverride parks the agent in FailedHolding. It listens for a
// heartbeat directive that tells it to retry a stage (e.g. Storage
// with wipe-override armed) and re-enters runStage from that point.
func waitForOverride(ctx context.Context, c *Client, fwd *logForwarder, mux *SensorMux, hb <-chan HeartbeatResponse, claim *ClaimResponse) error {
	fwd.info("holding: awaiting operator decision (heartbeat directive or ctx cancel)")
	for {
		select {
		case <-ctx.Done():
			return ctx.Err()
		case cmd, ok := <-hb:
			if !ok {
				return nil
			}
			if cmd.Cmd != "retry_stage" || cmd.Stage == "" {
				continue
			}
			fwd.info("operator override: retrying stage " + cmd.Stage)
			var ovr overrideFlags
			if len(cmd.OverrideFlags) > 0 {
				_ = json.Unmarshal(cmd.OverrideFlags, &ovr)
			}
			outcome := runStageCancellable(ctx, cmd.Stage, claim, fwd, c, mux, ovr)
			if outcome.Cancelled {
				fwd.warn("stage cancelled by operator; posting result and exiting")
				_, _ = postResult(ctx, c, cmd.Stage, outcome)
				return powerOffAndReturn(fwd)
			}
			resp, err := postResult(ctx, c, cmd.Stage, outcome)
			if err != nil {
				fwd.error("override: submit result: " + err.Error())
				continue
			}
			fwd.info(fmt.Sprintf("override stage %s → next_state=%s", cmd.Stage, resp.NextState))
			if resp.NextState == "FailedHolding" {
				// Still broken; keep holding.
				continue
			}
			if resp.NextState == "Completed" {
				return nil
			}
			// Successful retry — continue walking the pipeline from the
			// state the orchestrator advanced us into.
			if nextStage := stageForState(resp.NextState); nextStage != "" {
				for nextStage != "" {
					select {
					case <-ctx.Done():
						return ctx.Err()
					default:
					}
					fwd.info("stage: starting " + nextStage)
					out := runStageCancellable(ctx, nextStage, claim, fwd, c, mux, overrideFlags{})
					if out.Cancelled {
						fwd.warn("stage cancelled by operator; posting result and exiting")
						_, _ = postResult(ctx, c, nextStage, out)
						return powerOffAndReturn(fwd)
					}
					rr, err := postResult(ctx, c, nextStage, out)
					if err != nil {
						return err
					}
					if rr.NextState == "FailedHolding" || rr.NextState == "Completed" || rr.NextState == "" {
						return nil
					}
					nextStage = stageForState(rr.NextState)
				}
			}
			return nil
		}
	}
}

// requestHold fetches the per-run pubkey and installs it into
// /root/.ssh/authorized_keys so the operator can SSH in.
func requestHold(ctx context.Context, c *Client, fwd *logForwarder) error {
	fwd.warn("entering FailedHolding; requesting hold key")
	resp, err := c.Hold(ctx, localIP())
	if err != nil {
		fwd.error("hold request failed: " + err.Error())
		return err
	}
	authPath := "/root/.ssh/authorized_keys"
	if err := os.MkdirAll(filepath.Dir(authPath), 0o700); err != nil {
		fwd.error("mkdir .ssh: " + err.Error())
		return err
	}
	f, err := os.OpenFile(authPath, os.O_APPEND|os.O_CREATE|os.O_WRONLY, 0o600)
	if err != nil {
		fwd.error("open authorized_keys: " + err.Error())
		return err
	}
	defer func() { _ = f.Close() }()
	if _, err := fmt.Fprintln(f, resp.AuthorizedKey); err != nil {
		fwd.error("write authorized_keys: " + err.Error())
		return err
	}
	fwd.info("hold key installed; SSH is available to root@" + localIP())
	return nil
}

func inventorySummary(inv *spec.Inventory) string {
	populated := 0
	for _, d := range inv.Memory.Modules {
		if d.Populated {
			populated++
		}
	}
	slots := ""
	if len(inv.Memory.Modules) > 0 {
		slots = fmt.Sprintf(" (%d/%d slots)", populated, len(inv.Memory.Modules))
	}
	return fmt.Sprintf("cpu=%q cores=%d ram=%dGiB%s disks=%d nics=%d gpus=%d psu=%d",
		inv.CPU.Model, inv.CPU.LogicalCores, inv.Memory.TotalGiB, slots,
		len(inv.Disks), len(inv.NICs), len(inv.GPUs), len(inv.PSU))
}

// firmwareSummary renders the one-liner surfaced in the stage tile:
// per-component counts so an operator can see "bios=1 nic=2 nvme_fw=1"
// without opening the report.
func firmwareSummary(snaps []probes.FirmwareSnapshot) string {
	counts := map[string]int{}
	for _, s := range snaps {
		counts[s.Component]++
	}
	if len(counts) == 0 {
		return "no firmware readable"
	}
	keys := []string{"bios", "bmc", "nic", "hba", "nvme_fw", "microcode"}
	parts := make([]string, 0, len(keys))
	for _, k := range keys {
		if n := counts[k]; n > 0 {
			parts = append(parts, fmt.Sprintf("%s=%d", k, n))
		}
	}
	return strings.Join(parts, " ")
}

// thermalSidecar posts a batch of /sys/class/hwmon samples every 5s.
// Idempotent: a dead sensor just drops out of the next batch. Errors
// are logged but never fatal — we'd rather have a run with partial
// thermal data than kill the agent over an I/O hiccup.
func thermalSidecar(ctx context.Context, mux *SensorMux, fwd *logForwarder) {
	t := time.NewTicker(5 * time.Second)
	defer t.Stop()
	for {
		select {
		case <-ctx.Done():
			return
		case <-t.C:
			samples := probes.Thermals()
			if len(samples) == 0 {
				continue
			}
			out := make([]SensorSample, 0, len(samples))
			for _, s := range samples {
				out = append(out, SensorSample{Kind: s.Kind, Key: s.Key, Value: s.Value, Unit: s.Unit})
			}
			mux.Send(out)
		}
	}
}

func heartbeatLoop(ctx context.Context, c *Client, fwd *logForwarder, out chan<- HeartbeatResponse) {
	t := time.NewTicker(10 * time.Second)
	defer t.Stop()
	for {
		select {
		case <-ctx.Done():
			return
		case <-t.C:
			hbCtx, cancel := context.WithTimeout(ctx, 5*time.Second)
			resp, err := c.Heartbeat(hbCtx)
			cancel()
			if err != nil {
				fwd.warn("heartbeat error: " + err.Error())
				continue
			}
			if resp.Cmd == "abort" {
				fwd.warn("orchestrator said abort; stopping loop")
				return
			}
			if resp.Cmd == "shutdown" {
				fwd.info("orchestrator said shutdown; powering off host")
				// Best effort: systemd then sysvinit fallback. Either way,
				// return so the agent process stops issuing heartbeats.
				if err := exec.Command("systemctl", "poweroff").Run(); err != nil {
					fwd.warn("systemctl poweroff failed: " + err.Error())
					_ = exec.Command("shutdown", "-h", "now").Run()
				}
				return
			}
			if resp.Cmd == "cancel_stage" {
				fwd.warn("orchestrator said cancel_stage; cancelling in-flight stage ctx")
				if v := stageCancel.Load(); v != nil {
					if fn, ok := v.(context.CancelFunc); ok && fn != nil {
						fn()
					}
				}
				continue
			}
			if resp.Cmd == "retry_stage" {
				select {
				case out <- *resp:
				default:
				}
			}
		}
	}
}

func callWithBackoff(ctx context.Context, label string, f func(context.Context) error) error {
	backoff := 2 * time.Second
	for attempt := 1; ; attempt++ {
		callCtx, cancel := context.WithTimeout(ctx, 10*time.Second)
		err := f(callCtx)
		cancel()
		if err == nil {
			return nil
		}
		if attempt > 20 {
			return err
		}
		log.Printf("agent: %s attempt %d failed: %v (retry in %s)", label, attempt, err, backoff)
		select {
		case <-ctx.Done():
			return ctx.Err()
		case <-time.After(backoff):
		}
		if backoff < 30*time.Second {
			backoff *= 2
		}
	}
}

func localIP() string {
	addrs, err := net.InterfaceAddrs()
	if err != nil {
		return ""
	}
	for _, a := range addrs {
		ipnet, ok := a.(*net.IPNet)
		if !ok || ipnet.IP.IsLoopback() {
			continue
		}
		v4 := ipnet.IP.To4()
		if v4 != nil {
			return v4.String()
		}
	}
	return ""
}

// ----- log forwarder -----------------------------------------------------

type logForwarder struct {
	c      *Client
	mu     sync.Mutex
	buf    []LogLine
	stage  string // set via SetStage; empties via ClearStage
	wg     sync.WaitGroup
	cancel context.CancelFunc
}

func newLogForwarder(parent context.Context, c *Client) *logForwarder {
	ctx, cancel := context.WithCancel(parent)
	f := &logForwarder{c: c, cancel: cancel}
	f.wg.Add(1)
	go f.loop(ctx)
	return f
}

func (f *logForwarder) loop(ctx context.Context) {
	defer f.wg.Done()
	t := time.NewTicker(2 * time.Second)
	defer t.Stop()
	for {
		select {
		case <-ctx.Done():
			f.flush()
			return
		case <-t.C:
			f.flush()
		}
	}
}

func (f *logForwarder) push(level, text string) {
	stamp := time.Now().UTC().Format(time.RFC3339Nano)
	log.Printf("[%s] %s", level, text)
	f.mu.Lock()
	f.buf = append(f.buf, LogLine{TS: stamp, Level: level, Stage: f.stage, Text: text})
	f.mu.Unlock()
}

func (f *logForwarder) info(s string)  { f.push("info", s) }
func (f *logForwarder) warn(s string)  { f.push("warn", s) }
func (f *logForwarder) error(s string) { f.push("error", s) }

// SetStage tags subsequent log lines with a stage name so the orchestrator
// can fan them out on a per-stage SSE event. Safe to call concurrently
// with push — we take the same mutex.
func (f *logForwarder) SetStage(stage string) {
	f.mu.Lock()
	f.stage = stage
	f.mu.Unlock()
}

// ClearStage reverts to untagged (framing-level) logging. Defer this
// on entry to runStage so hold/override paths don't leak stage context.
func (f *logForwarder) ClearStage() {
	f.mu.Lock()
	f.stage = ""
	f.mu.Unlock()
}

func (f *logForwarder) flush() {
	f.mu.Lock()
	if len(f.buf) == 0 {
		f.mu.Unlock()
		return
	}
	lines := f.buf
	f.buf = nil
	f.mu.Unlock()

	ctx, cancel := context.WithTimeout(context.Background(), 5*time.Second)
	defer cancel()
	if err := f.c.Log(ctx, lines); err != nil {
		log.Printf("log forward failed: %v", err)
	}
}

func (f *logForwarder) close() {
	f.cancel()
	f.wg.Wait()
}