feat(run): durable checkpoint + resume (wire Ports.Checkpointer)
The kernel defined run.Ports.Checkpointer + the checkpoint battery but never drove them (the documented "P2 follow-up"). This wires durable recovery into the run loop so a run interrupted by shutdown can resume on the next boot instead of being lost — the executus-side half of mort's durable-agent-recovery parity (mort #1355). Kernel (run/): - Ports.Checkpointer is now a CheckpointerFactory (Begin per run → a per-run Checkpointer, or nil for a non-durable run). The single per-instance Checkpointer couldn't distinguish runs; a factory mints one per run, matching mort's agentexec.CheckpointerFactory. - RunInfo gains GuildID + ModelTier (so the factory can build resume meta); RunCheckpointState gains CompletedPhases + ActivePhase (+ PhaseOutput). - run/checkpoint.go: ResumeState + WithResumeState / WithExistingCheckpointer context carriers, classifyCheckpointOutcome (success→Complete, shutdown→leave for boot recovery, else→Fail using run.ErrShutdown), and finalizeCheckpoint. - run/executor.go: resolve the per-run checkpointer (existing-from-ctx on a recovery re-run, else factory.Begin); single-loop wraps the step observer to accumulate the transcript + Save each step (host throttles), and a recovered run seeds the saved transcript via WithHistory and continues with no new input; finalize on exit. - run/phases.go: phase-boundary checkpointing — record completed phases after each phase; a resumed run skips already-completed phases (the interrupted phase re-runs from its start — boundary-granular, documented; only the single-loop path resumes mid-loop). Battery (checkpoint/): NewFactory wires the battery into the factory port (per-run handle, meta derived from RunInfo); RunCheckpoint + handle.Save carry the phase fields. Tests (run/checkpoint_test.go): the finalize decision matrix; single-loop Save+Complete; terminal-error Fail; resume seeds history; phase-boundary Saves completed phases; resume skips completed phases. Full ./... green. Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
This commit is contained in:
@@ -4,9 +4,9 @@
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// run.Ports.Checkpointer.
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//
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// Mort backs CheckpointStore with its durable-job table; Memory() is the
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// zero-dependency default; contrib/store can add a SQLite one. NOTE: the
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// executor's call into run.Ports.Checkpointer is a P2 follow-up — this battery
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// provides the seam + impls ahead of that wiring.
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// zero-dependency default; contrib/store can add a SQLite one. The executor calls
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// run.Ports.Checkpointer (a CheckpointerFactory) during the run loop; NewFactory
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// wires this battery into that seam.
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package checkpoint
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import (
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@@ -14,6 +14,8 @@ import (
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"time"
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"gitea.stevedudenhoeffer.com/steve/majordomo/llm"
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"gitea.stevedudenhoeffer.com/steve/executus/run"
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)
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// RunCheckpointMeta is the run attribution needed to resume a run from scratch
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@@ -32,11 +34,12 @@ type RunCheckpointMeta struct {
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// RunCheckpoint is one persisted snapshot of a run's resumable progress.
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type RunCheckpoint struct {
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Meta RunCheckpointMeta
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Messages []llm.Message // conversation so far
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Iteration int // completed agent-loop iterations
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ActivePhase string // current phase name (multi-phase agents); "" otherwise
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UpdatedAt time.Time
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Meta RunCheckpointMeta
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Messages []llm.Message // conversation so far (single-loop or active phase)
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Iteration int // completed agent-loop iterations
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CompletedPhases []run.PhaseOutput // finished phases, in order (multi-phase agents)
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ActivePhase string // current phase name (multi-phase agents); "" otherwise
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UpdatedAt time.Time
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}
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// CheckpointStore persists run checkpoints keyed by run id. A live checkpoint
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+44
-4
@@ -54,10 +54,12 @@ func (h *handle) Save(ctx context.Context, st run.RunCheckpointState) error {
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// caller believes was saved. (A run drives one Save goroutine, so the brief
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// unguarded window here can't double-write.)
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if err := h.store.Save(ctx, RunCheckpoint{
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Meta: h.meta,
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Messages: st.Messages,
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Iteration: st.Iteration,
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UpdatedAt: now,
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Meta: h.meta,
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Messages: st.Messages,
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Iteration: st.Iteration,
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CompletedPhases: st.CompletedPhases,
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ActivePhase: st.ActivePhase,
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UpdatedAt: now,
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}); err != nil {
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return err
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}
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@@ -81,3 +83,41 @@ var _ run.Checkpointer = noop{}
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func (noop) Save(context.Context, run.RunCheckpointState) error { return nil }
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func (noop) Complete(context.Context) error { return nil }
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func (noop) Fail(context.Context, error) error { return nil }
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// factory is a run.CheckpointerFactory that mints a per-run handle over store,
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// deriving the per-run meta from the kernel's RunInfo. It is the battery's glue
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// for the Ports.Checkpointer (factory) seam: every run becomes durable (the
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// store persists snapshots; a host wanting lazy/short-run skipping uses its own
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// factory, as mort does over its durable-job table).
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type factory struct {
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store CheckpointStore
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throttle time.Duration
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now func() time.Time
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}
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var _ run.CheckpointerFactory = (*factory)(nil)
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// NewFactory returns a run.CheckpointerFactory backed by store: each run gets a
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// per-run Checkpointer (throttled to at most once per throttle). A nil store
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// yields factory.Begin returning a no-op Checkpointer.
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func NewFactory(store CheckpointStore, throttle time.Duration) run.CheckpointerFactory {
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return &factory{store: store, throttle: throttle}
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}
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// Begin mints the per-run Checkpointer. The prompt is read from
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// info.Inputs["prompt"] when present so a recovered run can re-dispatch.
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func (f *factory) Begin(_ context.Context, info run.RunInfo) (run.Checkpointer, error) {
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prompt, _ := info.Inputs["prompt"].(string)
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meta := RunCheckpointMeta{
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RunID: info.RunID,
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AgentID: info.SubjectID,
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AgentName: info.Name,
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CallerID: info.CallerID,
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ChannelID: info.ChannelID,
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GuildID: info.GuildID,
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Prompt: prompt,
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ModelTier: info.ModelTier,
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ParentRunID: info.ParentRunID,
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}
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return New(f.store, meta, f.throttle, f.now), nil
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}
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@@ -0,0 +1,94 @@
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package run
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import (
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"context"
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"errors"
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"gitea.stevedudenhoeffer.com/steve/majordomo/llm"
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)
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// Durable-recovery plumbing for the executor. The Checkpointer port (set via
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// Ports.Checkpointer, a CheckpointerFactory) persists a run's resumable progress
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// during the loop; on boot a host re-dispatches an interrupted run through the
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// executor with a ResumeState (the saved transcript / completed phases) so it
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// CONTINUES rather than restarting, reusing the SAME durable record via an
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// existing Checkpointer. Both are carried into Run via the context (mirrors
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// mort's agentexec.WithResumeState / WithExistingCheckpointer).
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// ResumeState carries a recovered run's prior progress into Run so the run
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// continues instead of restarting. The host's recovery path sets it via
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// WithResumeState; the executor reads it (single-loop seeds the saved transcript
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// as history; multi-phase skips completed phases and seeds the active phase).
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type ResumeState struct {
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History []llm.Message // single-loop transcript OR active-phase transcript
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CompletedPhases []PhaseOutput // multi-phase: outputs of finished phases, in order
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ActivePhase string // multi-phase: the phase that was in flight
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}
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type resumeStateKey struct{}
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// WithResumeState carries a recovered run's prior progress into Run.
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func WithResumeState(ctx context.Context, rs *ResumeState) context.Context {
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return context.WithValue(ctx, resumeStateKey{}, rs)
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}
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func resumeStateFromContext(ctx context.Context) *ResumeState {
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rs, _ := ctx.Value(resumeStateKey{}).(*ResumeState)
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return rs
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}
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type existingCheckpointerKey struct{}
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// WithExistingCheckpointer carries a pre-existing Checkpointer into Run so a
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// recovery re-run reuses the SAME durable record (the executor uses it instead of
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// calling Ports.Checkpointer.Begin).
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func WithExistingCheckpointer(ctx context.Context, cp Checkpointer) context.Context {
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return context.WithValue(ctx, existingCheckpointerKey{}, cp)
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}
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func existingCheckpointerFromContext(ctx context.Context) Checkpointer {
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cp, _ := ctx.Value(existingCheckpointerKey{}).(Checkpointer)
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return cp
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}
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// checkpointOutcome is the finalize decision for a durable run.
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type checkpointOutcome int
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const (
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checkpointComplete checkpointOutcome = iota
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checkpointLeaveRunning
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checkpointFail
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)
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// classifyCheckpointOutcome maps (run error, cancellation cause) to the durable
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// finalize action: success clears the checkpoint (Complete); a shutdown-caused
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// cancellation leaves the record so boot recovery picks it up (neither
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// Complete nor Fail); anything else (model error, tool loop, the run's own
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// deadline, a critic kill, a caller cancel) is terminal (Fail). Mirrors mort's
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// agentexec.classifyCheckpointOutcome.
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func classifyCheckpointOutcome(runErr, cause error) checkpointOutcome {
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switch {
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case runErr == nil:
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return checkpointComplete
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case errors.Is(cause, ErrShutdown):
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return checkpointLeaveRunning
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default:
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return checkpointFail
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}
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}
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// finalizeCheckpoint applies the outcome to the per-run checkpointer (nil-safe).
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// Runs on a detached context so a cancelled run still records its terminal state.
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func finalizeCheckpoint(ctx context.Context, cp Checkpointer, runErr error, cause error) {
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if cp == nil {
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return
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}
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switch classifyCheckpointOutcome(runErr, cause) {
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case checkpointComplete:
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_ = cp.Complete(detach(ctx))
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case checkpointFail:
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_ = cp.Fail(detach(ctx), runErr)
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case checkpointLeaveRunning:
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// Interrupted by shutdown: leave the record for boot recovery.
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}
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}
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@@ -0,0 +1,200 @@
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package run
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import (
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"context"
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"errors"
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"testing"
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"gitea.stevedudenhoeffer.com/steve/majordomo/llm"
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"gitea.stevedudenhoeffer.com/steve/majordomo/provider/fake"
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"gitea.stevedudenhoeffer.com/steve/executus/tool"
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)
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// fakeCheckpointer records every Save state + whether Complete/Fail fired.
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type fakeCheckpointer struct {
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saves []RunCheckpointState
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completed bool
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failed bool
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failErr error
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}
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func (c *fakeCheckpointer) Save(_ context.Context, st RunCheckpointState) error {
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c.saves = append(c.saves, st)
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return nil
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}
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func (c *fakeCheckpointer) Complete(context.Context) error { c.completed = true; return nil }
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func (c *fakeCheckpointer) Fail(_ context.Context, err error) error {
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c.failed = true
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c.failErr = err
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return nil
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}
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// fakeCheckpointFactory hands out one fakeCheckpointer and records the RunInfo.
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type fakeCheckpointFactory struct {
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cp *fakeCheckpointer
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info RunInfo
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}
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func (f *fakeCheckpointFactory) Begin(_ context.Context, info RunInfo) (Checkpointer, error) {
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f.info = info
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return f.cp, nil
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}
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// TestClassifyCheckpointOutcome covers the finalize decision matrix.
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func TestClassifyCheckpointOutcome(t *testing.T) {
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cases := []struct {
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name string
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err error
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cause error
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want checkpointOutcome
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}{
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{"success", nil, nil, checkpointComplete},
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{"shutdown", context.Canceled, ErrShutdown, checkpointLeaveRunning},
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{"critic-kill", context.Canceled, ErrCriticKill, checkpointFail},
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{"deadline", context.DeadlineExceeded, context.DeadlineExceeded, checkpointFail},
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{"model-error", errors.New("boom"), nil, checkpointFail},
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{"caller-cancel", context.Canceled, context.Canceled, checkpointFail},
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}
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for _, tc := range cases {
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if got := classifyCheckpointOutcome(tc.err, tc.cause); got != tc.want {
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t.Errorf("%s: classifyCheckpointOutcome = %v, want %v", tc.name, got, tc.want)
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}
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}
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}
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// TestCheckpoint_SingleLoopSaveAndComplete: a durable single-loop run gets a
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// per-run checkpointer (Begin), Saves its transcript each step, and Completes on
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// success (clearing the checkpoint). The RunInfo carries the resume meta.
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func TestCheckpoint_SingleLoopSaveAndComplete(t *testing.T) {
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models, _ := phaseProvider(t, fake.Reply("done"))
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cp := &fakeCheckpointer{}
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f := &fakeCheckpointFactory{cp: cp}
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ex := New(Config{Registry: tool.NewRegistry(), Models: models, Ports: Ports{Checkpointer: f}})
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res := ex.Run(context.Background(),
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RunnableAgent{ID: "a1", Name: "boss", ModelTier: "test-model"},
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tool.Invocation{RunID: "run-x", CallerID: "steve", ChannelID: "chan", GuildID: "g", SkillInputs: map[string]any{"prompt": "go"}},
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"go")
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if res.Err != nil {
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t.Fatalf("run error: %v", res.Err)
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}
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if f.info.RunID != "run-x" || f.info.SubjectID != "a1" || f.info.ModelTier != "test-model" || f.info.GuildID != "g" {
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t.Errorf("Begin RunInfo missing resume meta: %+v", f.info)
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}
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if len(cp.saves) == 0 {
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t.Error("expected at least one checkpoint Save during the run")
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} else if len(cp.saves[len(cp.saves)-1].Messages) == 0 {
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t.Error("checkpoint Save should carry the running transcript")
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}
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if !cp.completed {
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t.Error("a successful run must Complete (clear) its checkpoint")
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}
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if cp.failed {
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t.Error("a successful run must NOT Fail its checkpoint")
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}
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}
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// TestCheckpoint_TerminalErrorFails: a run that errors (not shutdown) Fails its
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// checkpoint (clears it — not a recovery candidate).
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func TestCheckpoint_TerminalErrorFails(t *testing.T) {
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models, _ := phaseProvider(t, fake.Fail(errors.New("model down")))
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cp := &fakeCheckpointer{}
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ex := New(Config{Registry: tool.NewRegistry(), Models: models, Ports: Ports{Checkpointer: &fakeCheckpointFactory{cp: cp}}})
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res := ex.Run(context.Background(),
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RunnableAgent{ID: "a1", ModelTier: "test-model"},
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tool.Invocation{RunID: "r", CallerID: "c", SkillInputs: map[string]any{"prompt": "go"}}, "go")
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if res.Err == nil {
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t.Fatal("expected a run error")
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}
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if !cp.failed {
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t.Error("a terminal (non-shutdown) error must Fail the checkpoint")
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}
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if cp.completed {
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t.Error("a failed run must NOT Complete its checkpoint")
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}
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}
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// TestCheckpoint_ResumeSeedsHistory: a run carrying a ResumeState seeds the saved
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// transcript as the model's opening messages (continues) instead of the input.
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func TestCheckpoint_ResumeSeedsHistory(t *testing.T) {
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models, fp := phaseProvider(t, fake.Reply("continued"))
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history := []llm.Message{llm.UserText("prior turn 1"), llm.AssistantText("prior answer 1")}
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ctx := WithResumeState(context.Background(), &ResumeState{History: history})
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ex := New(Config{Registry: tool.NewRegistry(), Models: models})
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res := ex.Run(ctx,
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RunnableAgent{ID: "a1", ModelTier: "test-model"},
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tool.Invocation{RunID: "r", CallerID: "c", SkillInputs: map[string]any{"prompt": "ignored-on-resume"}}, "ignored-on-resume")
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if res.Err != nil {
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t.Fatalf("run error: %v", res.Err)
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}
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got := fp.Calls()[0].Request.Messages
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if len(got) != len(history) {
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t.Fatalf("resume should seed the saved %d-message transcript, got %d messages", len(history), len(got))
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}
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}
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// TestCheckpoint_PhaseBoundarySavesCompleted: a durable multi-phase run records
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// the completed phases at each boundary, growing the list, and Completes on
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// success.
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func TestCheckpoint_PhaseBoundarySavesCompleted(t *testing.T) {
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models, _ := phaseProvider(t, fake.Reply("out-a"), fake.Reply("out-b"))
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cp := &fakeCheckpointer{}
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ex := New(Config{Registry: tool.NewRegistry(), Models: models, Ports: Ports{Checkpointer: &fakeCheckpointFactory{cp: cp}}})
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ra := RunnableAgent{
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ID: "p", ModelTier: "test-model",
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Phases: []Phase{{Name: "a", SystemPrompt: "A"}, {Name: "b", SystemPrompt: "B"}},
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}
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if res := ex.Run(context.Background(), ra, tool.Invocation{RunID: "r", CallerID: "c"}, "Q"); res.Err != nil {
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t.Fatalf("run error: %v", res.Err)
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}
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// The final phase-boundary Save must list both completed phases.
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var lastPhaseSave *RunCheckpointState
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for i := range cp.saves {
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if len(cp.saves[i].CompletedPhases) > 0 {
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lastPhaseSave = &cp.saves[i]
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}
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}
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if lastPhaseSave == nil || len(lastPhaseSave.CompletedPhases) != 2 {
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t.Fatalf("expected a phase-boundary Save listing 2 completed phases; saves=%+v", cp.saves)
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}
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if !cp.completed {
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t.Error("a successful phased run must Complete its checkpoint")
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}
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}
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// TestCheckpoint_ResumeSkipsCompletedPhases: a resumed multi-phase run skips
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// phases already in ResumeState.CompletedPhases (only the remaining phase calls
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// the model) and threads their outputs into the remaining phase's template.
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func TestCheckpoint_ResumeSkipsCompletedPhases(t *testing.T) {
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models, fp := phaseProvider(t, fake.Reply("out-b")) // ONLY phase b should call the model
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ctx := WithResumeState(context.Background(), &ResumeState{
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CompletedPhases: []PhaseOutput{{Name: "a", Output: "saved-a"}},
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})
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ex := New(Config{Registry: tool.NewRegistry(), Models: models})
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ra := RunnableAgent{
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ID: "p", ModelTier: "test-model",
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Phases: []Phase{
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{Name: "a", SystemPrompt: "A"},
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{Name: "b", SystemPrompt: "B saw {{.a}}"},
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},
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}
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res := ex.Run(ctx, ra, tool.Invocation{RunID: "r", CallerID: "c"}, "Q")
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if res.Err != nil {
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t.Fatalf("run error: %v", res.Err)
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}
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if res.Output != "out-b" {
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t.Fatalf("output = %q, want out-b", res.Output)
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}
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calls := fp.Calls()
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if len(calls) != 1 {
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t.Fatalf("only the un-completed phase b should call the model; got %d calls", len(calls))
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}
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if calls[0].Request.System != "B saw saved-a" {
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t.Errorf("resumed phase b should see the completed phase a's saved output; system = %q", calls[0].Request.System)
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}
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}
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+58
-8
@@ -165,7 +165,9 @@ func (e *Executor) Run(ctx context.Context, ra RunnableAgent, inv tool.Invocatio
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Name: ra.Name,
|
||||
CallerID: inv.CallerID,
|
||||
ChannelID: inv.ChannelID,
|
||||
GuildID: inv.GuildID,
|
||||
ParentRunID: inv.ParentRunID,
|
||||
ModelTier: tier,
|
||||
Inputs: inv.SkillInputs,
|
||||
StartedAt: started,
|
||||
MaxIterations: maxIter,
|
||||
@@ -180,6 +182,19 @@ func (e *Executor) Run(ctx context.Context, ra RunnableAgent, inv tool.Invocatio
|
||||
inv.RunState = stateAcc
|
||||
}
|
||||
|
||||
// Durable recovery (optional): a recovered run carries a ResumeState (prior
|
||||
// transcript / completed phases) + an existing Checkpointer in ctx so it
|
||||
// continues on the SAME durable record; a fresh run mints a per-run
|
||||
// Checkpointer via the factory (which decides durability — nil = non-durable).
|
||||
// nil-safe throughout.
|
||||
resume := resumeStateFromContext(ctx)
|
||||
ckpt := existingCheckpointerFromContext(ctx)
|
||||
if ckpt == nil && e.cfg.Ports.Checkpointer != nil {
|
||||
if c, cerr := e.cfg.Ports.Checkpointer.Begin(ctx, info); cerr == nil {
|
||||
ckpt = c
|
||||
}
|
||||
}
|
||||
|
||||
// Steer mailbox: lets session tools (via inv.AttachImages) feed multimodal
|
||||
// messages into the running conversation before its next step. Created BEFORE
|
||||
// the toolbox build so any tool's handler captures the live AttachImages seam.
|
||||
@@ -289,11 +304,11 @@ func (e *Executor) Run(ctx context.Context, ra RunnableAgent, inv tool.Invocatio
|
||||
}
|
||||
|
||||
// Shared agent options used by BOTH the single-loop path and every phase: the
|
||||
// tool-error guards, the step observer, and optional compaction. The toolbox +
|
||||
// step ceiling are NOT shared (they vary per phase), so they're added per path.
|
||||
// tool-error guards and optional compaction. The toolbox, step ceiling, AND
|
||||
// step observer are added per path (the observer is wrapped for checkpointing,
|
||||
// which differs single-loop vs per-phase).
|
||||
sharedOpts := []agent.Option{
|
||||
agent.WithToolErrorLimits(e.cfg.Defaults.MaxConsecutiveToolErrors, e.cfg.Defaults.MaxSameToolCallRepeats),
|
||||
agent.WithStepObserver(stepObserver),
|
||||
}
|
||||
if e.cfg.Compactor != nil && e.cfg.ContextTokens != nil {
|
||||
if threshold := e.compactionThreshold(tier); threshold > 0 {
|
||||
@@ -330,18 +345,47 @@ func (e *Executor) Run(ctx context.Context, ra RunnableAgent, inv tool.Invocatio
|
||||
// Single-loop run: the agent's base prompt + full toolbox, with the
|
||||
// critic's DYNAMIC step ceiling (WithMaxStepsFunc, so it can raise a
|
||||
// healthy-but-long run's budget mid-flight; falls back to maxIter).
|
||||
//
|
||||
// Checkpointing: wrap the step observer to accumulate the running transcript
|
||||
// and Save it each step (the host throttles). A recovered run seeds the saved
|
||||
// transcript as history and continues with no new input. acc starts from the
|
||||
// resume history (or the opening user message) and grows as steps complete.
|
||||
obs := stepObserver
|
||||
if ckpt != nil {
|
||||
acc := []llm.Message{multimodalUserMessage(input, inv.Images)}
|
||||
if resume != nil && len(resume.History) > 0 {
|
||||
acc = append([]llm.Message(nil), resume.History...)
|
||||
}
|
||||
obs = func(s agent.Step) {
|
||||
stepObserver(s)
|
||||
if s.Response != nil {
|
||||
acc = append(acc, s.Response.Message())
|
||||
}
|
||||
if len(s.Results) > 0 {
|
||||
acc = append(acc, llm.ToolResultsMessage(s.Results...))
|
||||
}
|
||||
_ = ckpt.Save(runCtx, RunCheckpointState{Messages: acc, Iteration: s.Index + 1})
|
||||
}
|
||||
}
|
||||
opts := append([]agent.Option{
|
||||
agent.WithToolbox(toolbox),
|
||||
critic.maxStepsOption(maxIter),
|
||||
agent.WithStepObserver(obs),
|
||||
}, sharedOpts...)
|
||||
ag := agent.New(model, e.systemPrompt(ra), opts...)
|
||||
runRes, runErr = runAgent(runCtx, ag, input, inv.Images, agent.WithSteer(steer))
|
||||
if resume != nil && len(resume.History) > 0 {
|
||||
// Resume: seed the saved transcript and continue (no new input — the
|
||||
// completed tool calls in the transcript are NOT re-run).
|
||||
runRes, runErr = ag.Run(runCtx, "", agent.WithSteer(steer), agent.WithHistory(resume.History))
|
||||
} else {
|
||||
runRes, runErr = runAgent(runCtx, ag, input, inv.Images, agent.WithSteer(steer))
|
||||
}
|
||||
} else {
|
||||
// Multi-phase pipeline: each phase runs its own prompt/tier/tools/step-cap
|
||||
// sequentially, threading outputs through {{.<PhaseName>}} templates. Reuses
|
||||
// the shared opts so audit/steps/critic-steer accumulate across every phase.
|
||||
// (Per-phase step caps are fixed — the critic's dynamic ceiling is not
|
||||
// propagated to phases — but its steer + hard deadline still apply.)
|
||||
// sequentially, threading outputs through {{.<PhaseName>}} templates. The
|
||||
// shared step observer (audit/steps/critic) is wired per phase by the phase
|
||||
// runner; checkpointing is phase-boundary granular (completed phases are
|
||||
// recorded so a resumed run skips them).
|
||||
runRes, runErr = e.runPhases(runCtx, ra, phaseDeps{
|
||||
baseModel: model,
|
||||
baseToolbox: toolbox,
|
||||
@@ -350,9 +394,15 @@ func (e *Executor) Run(ctx context.Context, ra RunnableAgent, inv tool.Invocatio
|
||||
stepObserver: stepObserver,
|
||||
steer: steer,
|
||||
rec: rec,
|
||||
checkpointer: ckpt,
|
||||
resume: resume,
|
||||
}, input, inv.Images)
|
||||
}
|
||||
|
||||
// Finalize durable recovery: clear the checkpoint on success/terminal failure,
|
||||
// or leave it for boot recovery when the run was interrupted by shutdown.
|
||||
finalizeCheckpoint(ctx, ckpt, runErr, context.Cause(runCtx))
|
||||
|
||||
status := statusFor(runCtx, runErr)
|
||||
if runRes != nil {
|
||||
res.Output = runRes.Output
|
||||
|
||||
+39
-2
@@ -64,6 +64,13 @@ type phaseDeps struct {
|
||||
stepObserver func(agent.Step)
|
||||
steer func() []llm.Message
|
||||
rec RunRecorder
|
||||
// checkpointer records phase-boundary progress (completed phases) for durable
|
||||
// recovery; nil = non-durable. resume carries a recovered run's completed
|
||||
// phases so they are skipped on re-run. Phase recovery is boundary-granular:
|
||||
// the interrupted (active) phase re-runs from its start (its mid-phase
|
||||
// transcript is NOT resumed — only the single-loop path resumes mid-loop).
|
||||
checkpointer Checkpointer
|
||||
resume *ResumeState
|
||||
}
|
||||
|
||||
// runPhases executes ra.Phases sequentially and returns a synthetic agent.Result
|
||||
@@ -73,10 +80,22 @@ type phaseDeps struct {
|
||||
// deadline/critic-kill — returns the error.
|
||||
func (e *Executor) runPhases(runCtx context.Context, ra RunnableAgent, deps phaseDeps, query string, images []llm.ImagePart) (*agent.Result, error) {
|
||||
outputs := make(map[string]string, len(ra.Phases))
|
||||
var completed []PhaseOutput
|
||||
var lastResult *agent.Result
|
||||
var lastOutput string
|
||||
var totalUsage llm.Usage
|
||||
|
||||
// Resume: pre-populate from the saved checkpoint so already-finished phases are
|
||||
// skipped. The interrupted (active) phase is NOT pre-populated, so it re-runs
|
||||
// from its start (boundary-granular recovery).
|
||||
if deps.resume != nil {
|
||||
for _, pc := range deps.resume.CompletedPhases {
|
||||
outputs[pc.Name] = pc.Output
|
||||
completed = append(completed, pc)
|
||||
lastOutput = pc.Output
|
||||
}
|
||||
}
|
||||
|
||||
// finish stamps the aggregated usage + final output onto the synthetic result.
|
||||
finish := func(err error) (*agent.Result, error) {
|
||||
if lastResult == nil {
|
||||
@@ -90,6 +109,12 @@ func (e *Executor) runPhases(runCtx context.Context, ra RunnableAgent, deps phas
|
||||
}
|
||||
|
||||
for i, phase := range ra.Phases {
|
||||
// Skip phases already completed on a resumed run (key presence, not output
|
||||
// emptiness — a legitimately-empty phase output still counts as done).
|
||||
if _, done := outputs[phase.Name]; done {
|
||||
lastOutput = outputs[phase.Name]
|
||||
continue
|
||||
}
|
||||
// A killed/timed-out/cancelled run must not start its next phase.
|
||||
if err := runCtx.Err(); err != nil {
|
||||
return finish(err)
|
||||
@@ -151,6 +176,16 @@ func (e *Executor) runPhases(runCtx context.Context, ra RunnableAgent, deps phas
|
||||
|
||||
outputs[phase.Name] = output
|
||||
lastOutput = output
|
||||
// Checkpoint the phase boundary: this phase is done, so a resumed run skips
|
||||
// it and continues from the next. (Copy the slice — the checkpointer may
|
||||
// hold/serialize it asynchronously.)
|
||||
completed = append(completed, PhaseOutput{Name: phase.Name, Output: output})
|
||||
if deps.checkpointer != nil {
|
||||
_ = deps.checkpointer.Save(runCtx, RunCheckpointState{
|
||||
CompletedPhases: append([]PhaseOutput(nil), completed...),
|
||||
ActivePhase: "",
|
||||
})
|
||||
}
|
||||
}
|
||||
|
||||
return finish(nil)
|
||||
@@ -192,11 +227,13 @@ func (e *Executor) runOnePhase(runCtx context.Context, ra RunnableAgent, deps ph
|
||||
maxIter = deps.baseMaxIter
|
||||
}
|
||||
// Per-phase opts: a fixed step ceiling for this phase (the critic's dynamic
|
||||
// ceiling is intentionally not propagated to phases) + the phase toolbox, on
|
||||
// top of the shared opts (tool-error limits, step observer, compactor).
|
||||
// ceiling is intentionally not propagated to phases) + the phase toolbox + the
|
||||
// shared step observer (audit/steps/critic), on top of the shared opts
|
||||
// (tool-error limits, compactor).
|
||||
opts := append([]agent.Option{
|
||||
agent.WithToolbox(toolbox),
|
||||
agent.WithMaxSteps(maxIter),
|
||||
agent.WithStepObserver(deps.stepObserver),
|
||||
}, deps.sharedOpts...)
|
||||
ag := agent.New(model, system, opts...)
|
||||
|
||||
|
||||
+31
-5
@@ -33,9 +33,10 @@ type Ports struct {
|
||||
Budget Budget
|
||||
// Critic optionally monitors a long run for hangs/runaways. nil = none.
|
||||
Critic Critic
|
||||
// Checkpointer persists resumable progress for durable recovery. nil = no
|
||||
// checkpointing (a run interrupted by shutdown is simply lost).
|
||||
Checkpointer Checkpointer
|
||||
// Checkpointer mints a per-run Checkpointer for durable recovery (it decides
|
||||
// per run whether the run is durable). nil = no checkpointing (a run
|
||||
// interrupted by shutdown is simply lost).
|
||||
Checkpointer CheckpointerFactory
|
||||
// Palette resolves SkillPalette / SubAgentPalette entries into delegation
|
||||
// tools (skill__<name> / agent__<name>). nil = those entries are inert.
|
||||
Palette PaletteSource
|
||||
@@ -66,7 +67,9 @@ type RunInfo struct {
|
||||
Name string
|
||||
CallerID string
|
||||
ChannelID string
|
||||
GuildID string // the originating guild/server id (empty for DMs/triggers)
|
||||
ParentRunID string
|
||||
ModelTier string // the run's resolved base tier (for checkpoint re-dispatch)
|
||||
Inputs map[string]any
|
||||
StartedAt time.Time
|
||||
// MaxIterations is the run's base tool-dispatch step ceiling, so a critic can
|
||||
@@ -172,6 +175,16 @@ type CriticHandle interface {
|
||||
|
||||
// --- Checkpointer ---
|
||||
|
||||
// CheckpointerFactory decides, per run, whether the run is durable and (if so)
|
||||
// mints the per-run Checkpointer that records its progress. It returns (nil, nil)
|
||||
// for a non-durable run (the common short-run case — no checkpointing overhead).
|
||||
// A storage error should be logged and degraded to (nil, nil) so a failing
|
||||
// checkpoint store never fails the run. Mirrors mort's
|
||||
// agentexec.CheckpointerFactory.
|
||||
type CheckpointerFactory interface {
|
||||
Begin(ctx context.Context, info RunInfo) (Checkpointer, error)
|
||||
}
|
||||
|
||||
// Checkpointer persists a run's resumable progress for durable recovery.
|
||||
// Mirrors mort's agentexec.RunCheckpointer.
|
||||
type Checkpointer interface {
|
||||
@@ -184,11 +197,24 @@ type Checkpointer interface {
|
||||
Fail(ctx context.Context, err error) error
|
||||
}
|
||||
|
||||
// RunCheckpointState is the resumable snapshot a Checkpointer persists. Kept
|
||||
// minimal here; the executor extends what it records during the merge.
|
||||
// RunCheckpointState is the resumable snapshot a Checkpointer persists.
|
||||
type RunCheckpointState struct {
|
||||
// Messages is the running transcript (single-loop run) OR the active phase's
|
||||
// transcript (multi-phase run). May be nil.
|
||||
Messages []llm.Message
|
||||
Iteration int
|
||||
// CompletedPhases is set only for multi-phase runs: the outputs of phases
|
||||
// already finished, in phase order. nil for single-loop runs.
|
||||
CompletedPhases []PhaseOutput
|
||||
// ActivePhase is the name of the in-progress phase (multi-phase only).
|
||||
ActivePhase string
|
||||
}
|
||||
|
||||
// PhaseOutput is one completed pipeline phase's name and output text, recorded in
|
||||
// a checkpoint so a resumed multi-phase run can skip already-finished phases.
|
||||
type PhaseOutput struct {
|
||||
Name string
|
||||
Output string
|
||||
}
|
||||
|
||||
// --- PaletteSource ---
|
||||
|
||||
Reference in New Issue
Block a user