Loop engineering means you stop being the person who types every prompt to a coding agent — and start designing a small system that discovers work, delegates it, checks it, remembers progress, and repeats. The leverage moves from prompt craft to loop design: six primitives that now ship inside tools like Claude Code and the Codex app instead of bespoke bash you maintain forever.
%%{init: {"theme": "base", "themeVariables": {"background": "transparent", "lineColor": "#000000"}}}%%
graph TD
subgraph Stack["Three layers"]
H[Harness engineering] --> L[Loop engineering]
L --> O[Orchestration layer]
end
H -->|one agent runtime| T[Tools memory sandbox]
L -->|schedule + verify| P[Six primitives]
O -->|fleet + PR lifecycle| R[Reactions state machine]
classDef agent fill:#8B0000,color:#fff
classDef hook fill:#189AB4,color:#fff
classDef decision fill:#444,color:#fff
class H,L,O agent
class T,P,R hook
Where the conversation landed in 2026
The shift is no longer niche. Boris Cherny, who leads Claude Code at Anthropic, described it on the Acquired podcast as: “I don’t prompt Claude anymore. I have loops running that prompt Claude and figure out what to do. My job is to write loops.” Peter Steinberger put the same idea on X: “You shouldn’t be prompting coding agents anymore. You should be designing loops that prompt your agents.” Both are saying the human job moved up one floor — from typing each turn to designing feedback systems.
That floor has three names in practice. Harness engineering is the runtime around one agent (tools, memory, permissions). Loop engineering is the harness that runs on a schedule, spawns helpers, and feeds itself from disk. Orchestration is the layer above when you need fleets of agents across worktrees, PRs, and CI — with automatic routing of failures back to the right session.
The universal five-stage cycle
| Stage | What happens | Typical tooling |
|---|---|---|
| Discover | Find work: CI failures, issues, diffs, inbox | Automations, /loop, triage skills |
| Plan | Break goal into steps with constraints | Skills, VISION.md, spec sub-agent |
| Execute | Edit code, run tools, open PRs | Worktrees, MCP connectors |
| Verify | Push against objective signals — not model opinion | Tests, lint, /goal evaluator, critic sub-agent |
| Iterate | Fix gaps and loop again | Stop hooks, reactions, state file |
A prompt gives instructions for one turn. A loop gives a job: discover → plan → execute → verify → iterate until done. You set the goal; the loop runs itself.
Open loops vs closed loops
| Open loop | Closed loop | |
|---|---|---|
| Nature | Exploratory; wide search space | Bounded path you designed |
| Risk | Token burn; “slop machine” without gates | Cheaper; predictable |
| Needs | Large budget + strong evaluators | Clear goal, defined steps, stop condition |
| Start here? | Research spikes, benchmarks | Production coding, triage, migrations |
Closed loops need five ingredients on disk: goal (precise done), context (VISION.md, ARCHITECTURE.md, RULES.md), action (scoped tools), feedback (tests, lint, structured errors), and a stop condition (/goal text, Stop hook, or orchestrator brief). Without a quality gate, AI drifts; with one, it improves.
Single-agent loop vs fleet loop
| Single-agent loop | Fleet loop | |
|---|---|---|
| Shape | One brain runs discover→verify end-to-end | Orchestrator splits work across specialists |
| Good for | Focused refactors, /goal migrations | Large features, parallel PRs, research→build→QA chains |
| Token profile | ~50K–200K tokens per medium coding task | ~500K–2M+ when orchestrator + 3+ specialists run |
| Example split | Explore → implement → verify sub-agents | Research specialist → engineering specialist → QA specialist, each with its own loop |
What changed in agentic development
For roughly two years, “good AI coding” meant writing strong prompts and feeding enough context each turn. You typed, read, typed again — the agent was a power tool and you held the handle every step.
Loop engineering is the next layer: a recursive goal where you define purpose and done, and the system iterates until a verifiable condition holds. You design once; the loop pokes agents on a schedule or across turns. This sits one floor above agent harness engineering (the environment one agent runs in) and the factory model (the system that builds software) — same family of ideas, but the harness now runs on a timer, spawns helpers, and feeds itself from disk-based memory.
The six primitives every loop needs
| # | Primitive | Job in the loop | Without it |
|---|---|---|---|
| 1 | Automations | Scheduled discovery and triage | You manually check CI, issues, and diffs |
| 2 | Worktrees | Isolate parallel agent checkouts | Two agents overwrite the same files |
| 3 | Skills | Project knowledge on disk (SKILL.md) | Agent re-guesses conventions every run |
| 4 | Connectors (MCP) | Issues, DB, Slack, staging APIs | Agent only sees the filesystem |
| 5 | Sub-agents | Separate maker and checker roles | One model grades its own homework |
| 6 | State / memory | Markdown, Linear board, AGENTS.md | Model forgets between runs; loop restarts blind |
The agent forgets; the repo does not. Long-running loops depend on external state — not context window — to remember what was tried, what passed, and what is next. Common context files beyond SKILL.md: VISION.md (what success looks like), ARCHITECTURE.md (stack and layout), RULES.md (forbidden actions), GUARDRAILS.md (always-on checklists), and AGENTS.md (repo map for agents).
Codex app vs Claude Code — same shape, different names
| Primitive | Codex app | Claude Code |
|---|---|---|
| Automations | Automations tab: project, prompt, cadence, local or worktree env; Triage inbox; thread vs standalone runs | /loop, Desktop scheduled tasks, Cloud Routines (/schedule), hooks, GitHub Actions |
| Worktrees | Built-in per thread | git worktree, --worktree, isolation: worktree on subagents |
| Skills | SKILL.md, invoke with $name or /skills | Same SKILL.md folder format; bundled /loop, /code-review |
| Connectors | MCP connectors + plugins | MCP servers + plugins; routine connectors on claude.ai |
| Sub-agents | TOML in .codex/agents/ | .claude/agents/, agent teams |
| State | Markdown / Linear via connector; thread memory | AGENTS.md, progress files, prd.json-style task queues |
Once you see the shared shape, the debate shifts from “which tool” to “which loop design still works in either seat.”
1. Automations — the heartbeat
Automations turn a one-off agent run into a loop. In the Codex app you configure project, prompt, schedule, and environment (local checkout or background worktree). Runs with findings land in a Triage inbox; empty runs archive themselves. Internal uses include daily issue triage, CI failure summaries, commit briefings, and regression hunts. Automations can call $skill-name so recurring logic stays maintainable.
Claude Code reaches the same outcome via /loop (interval reruns), cron scheduling, lifecycle hooks, Desktop scheduled tasks (persistent while app is open), Cloud Routines (runs when laptop is closed), or GitHub Actions for headless runs.
Interactive pick: /goal vs /loop vs Stop hooks
| Mechanism | Next turn starts when… | Stops when… | Best for |
|---|---|---|---|
/goal (Claude) | Previous turn finishes | Separate evaluator model confirms condition (reads transcript only) | Migrations, refactors, “all tests green” |
/goal (Codex) | Thread idle after turn | Evidence in thread supports completion; pause/resume/clear/budget | Multi-hour tuning, benchmarks, long refactors |
/loop | Time interval elapses | You stop it or agent decides done | Polling deploys, periodic summaries, PR babysitting |
| Stop hook | Previous turn finishes | Your script, prompt hook, or agent hook decides | Ralph-style loops, org-wide completion rules |
# Claude Code — run until tests and lint are clean (v2.1.139+)
/goal all tests in test/auth pass and the lint step is clean
# Check spend and evaluator reasoning
/goal
# Stop early
/goal clear
# Headless single invocation
claude -p "/goal CHANGELOG.md has an entry for every PR merged this week"
# Codex — long-running performance goal (cookbook pattern)
/goal Reduce p95 checkout latency below 120 ms, verified by the checkout benchmark,
while keeping the correctness suite green. If blocked, stop with evidence./goal on Claude Code starts a turn immediately; after each turn Haiku (by default) judges yes/no from the transcript — it does not run tools. Codex /goal is thread-scoped with explicit budget accounting and pause/resume. Pair either with auto mode so each turn skips per-tool confirmations.
2. Worktrees — parallel without collisions
Two agents editing the same file is the same failure mode as two engineers on one branch without coordination. A git worktree is a separate working directory on its own branch, sharing history but not files. Codex threads use worktrees natively; Claude Code offers --worktree sessions and isolation: worktree on subagents that clean up after themselves.
Worktrees remove mechanical collision; your review bandwidth still caps how many parallel agents you can actually supervise.
3. Skills — stop paying intent debt every session
Agents start cold. Every missing convention becomes a confident guess — intent debt. A skill is intent written outside the chat: a folder with SKILL.md, optional scripts, references, and assets. Both Codex and Claude Code load skills when you invoke $name or when the task matches a tight, boring description (clever descriptions match too often).
# Example skill layout
my-project-skill/
SKILL.md # conventions, build steps, forbidden patterns
scripts/
references/Skill vs plugin: the skill is the authoring format; a plugin bundles skills and connectors for teammates to install once.
4. Connectors — act in your real environment
MCP connectors let the loop read Linear/Jira, query databases, hit staging APIs, and post to Slack. That is the difference between “here is the fix” and “open the PR, link the ticket, ping the channel when CI is green.” Plugins package connectors with skills so onboarding is one install, not tribal memory.
Feedback signals that keep loops honest
| Signal type | Examples | Strength |
|---|---|---|
| Deterministic oracles | CI, unit tests, type checks, linters, git diff, scalar metrics (e.g. benchmark p95) | Strongest — pass/fail without model judgment |
| Perceptual / visual | Playwright, browser MCP tools, layout screenshots | Medium — catches UI regressions code tests miss |
| Critic sub-agents | Separate reviewer agent; forces retry or stop | Medium — judgment, but not the worker context |
| Persistent context | GUARDRAILS.md, skills, checklists loaded every run | Always-on oracle |
| LLM self-critique only | “Does this look good?” from same model | Weakest — rationalises its own mistakes |
Strongest systems stack multiple signal types: deterministic for reliability, visual/critic for judgment, human gates on high-stakes merges. Signals must route back automatically — full logs, diffs, scores — without you copy-pasting CI output each turn.
5. Sub-agents — maker vs checker
/goal’s separate done-evaluator.The model that wrote the code is too lenient grading itself. A second agent — different instructions, sometimes a different model — catches rationalised mistakes. Typical trio: explore, implement, verify against spec. In fleet setups, a validator agent reports truth without fixing — failures loop back to the builder.
# Codex — custom subagent (simplified .codex/agents/security-reviewer.toml)
name = "security-reviewer"
description = "Read-only security pass on diffs"
instructions = "Find auth, injection, and secret-leak risks. No edits."
model = "strong"
reasoning_effort = "high"Sub-agents cost extra tokens (each runs its own model + tools). Spend them where a second opinion unlocks unattended runs — the only reason you can walk away from a loop.
Orchestration — when one loop is not enough
Single-session /goal loops solve “finish this migration without me re-prompting.” Fleet-scale work needs an orchestration layer: deterministic plumbing plus an orchestrator agent for judgment.
| Layer | Job | Examples |
|---|---|---|
| Deterministic plumbing | Route environmental feedback automatically | CI fail → inject logs into worker session; PR conflict → notify right agent; lifecycle state machine (working → ci_failed → review_pending → merged) |
| Orchestrator agent | Decompose goals, write briefs, batch parallel work | Research agent → spec → tracking issue → N workers in isolated worktrees |
| Human gates | Vision, acceptance, high-risk merges | Triage inbox, PR approval — optimise human time, not remove humans |
Open-source reference implementations like Agent Orchestrator (npm install -g @aoagents/ao) ship reactions engines, worktree isolation, and orchestrator prompts out of the box. The pattern: inner agents execute in bounded loops; outer orchestrator coordinates; environmental signals keep loops honest; you stay on vision and judgment.
Walkthrough: one morning triage loop
%%{init: {"theme": "base", "themeVariables": {"background": "transparent", "lineColor": "#000000"}}}%%
sequenceDiagram
participant Auto as Morning automation
participant Skill as Triage skill
participant State as STATE.md
participant WT as Worktree
participant Maker as Fix sub-agent
participant Check as Review sub-agent
participant MCP as Connectors
Auto->>Skill: Run on schedule
Skill->>State: Write CI failures + issues
loop Each actionable item
Auto->>WT: Open isolated checkout
WT->>Maker: Draft fix
Maker->>Check: Submit diff
Check-->>Maker: Approve or reject
Maker->>MCP: Open PR + update ticket
end
Auto->>State: Log done / blocked for human inbox
- 06:00 — Automation fires; triage skill reads yesterday’s CI, open issues, recent commits.
- Findings — Written to
STATE.mdor a Linear board (memory outside the chat). - Per item — New worktree → maker sub-agent drafts fix → checker sub-agent runs against project skills + tests.
- Ship — Connectors open PR and update tickets; blocked items land in your inbox.
- Tomorrow — State file tells the loop what was tried, passed, or still open.
You designed this once. You did not prompt each step — that is the whole point.
Prompt engineer vs loop engineer
| Prompt engineer | Loop engineer |
|---|---|
| Crafts better instructions per turn | Designs feedback cycles and stop conditions |
| Linguistic skill | Systems / software engineering skill |
| Better single output | Reliable verified outcomes across runs |
| You review manually each time | System self-corrects against oracles |
| You are the feedback loop | The loop is the feedback loop |
| “Write me a function” | “Write → test → fix until green” |
Self-check: is your loop healthy?
| Question | Healthy loop | Leaky loop |
|---|---|---|
| What proves “done”? | Tests, lint, measurable condition in /goal | Agent says “looks good” |
| Where does memory live? | Repo file or issue tracker | Only in chat context |
| Who verifies? | Separate sub-agent or evaluator model | Same agent that wrote code |
| What pushes back? | Layered oracles (CI + critic + human gate) | Self-critique only |
| Parallelism? | One worktree per agent | Shared checkout |
| Token budget? | Turn cap in condition or manual clear | Open-ended overnight /goal |
| Your role? | Review merged outcomes you understand | Press go and hope |
What loops do not remove — three sharper risks
Verification stays human
An unattended loop is also an unattended mistake machine. Even with a verifier sub-agent, “done” is a claim, not proof. Ship code you confirmed works — especially when diff sizes balloon because agents touch more files than necessary.
Comprehension debt accelerates
The faster the loop ships code you did not write, the wider the gap between what exists and what you understand. Read the reasoning, skim the diff, trace the decision log — or the loop makes the debt grow faster, not slower.
Cognitive surrender
When automation feels smooth, it is tempting to stop having opinions. Loop design with judgement keeps you the engineer; loop design to avoid thinking is the same UI with opposite outcomes. Two teams can run identical loops — one moves faster on work they deeply understand; the other outsources understanding entirely. The loop cannot tell the difference. You can.
Parallel pattern: scheduled content factories
The same week loop engineering went mainstream for coding, creators published parallel “factory” playbooks for media. @0x_fokki’s X Article I Built an AI Animation Factory That Runs 24/7 is not a coding-agent harness — Claude is used as a scriptwriter, not a repo editor — but it shows the same design move: stop hand-driving each step, design a pipeline that runs on a schedule with human approval gates.
Fokki’s pipeline chains six tools end-to-end:
Claude → Midjourney → Runway → ElevenLabs → Suno → Make
script → frames → motion → voice → music → publishOne Make scenario runs Monday and Thursday at 08:00: pull scripts from Google Drive, batch Midjourney scene prompts, download frames, send dialogue to ElevenLabs, pair images with Runway motion clips, assemble in a CapCut template, upload to YouTube with generated metadata, clip a 30-second X preview, post Patreon early access, and ping Telegram on completion. A separate on-demand webhook turns client briefs into finished explainers in shared Drive — quoted turnaround ~6 hours after a one-time ~5-hour setup.
Four SKUs share the pipeline: animated story series (6–10 min), brand explainers (60–90 sec), motion comics, and children’s bedtime channels. The human job is narrow: pick the story, pick the style, approve the output — roughly four hours of direction for a “24/7” factory, per the author.
| Loop-engineering primitive | Fokki factory analogue | Key difference |
|---|---|---|
| Automations | Make.com schedule + webhook | No /goal or hooks — cron-style triggers only |
| Skills / context on disk | Reusable Midjourney character sheets, CapCut templates, voice cast notes | Creative consistency prompts, not SKILL.md |
| Sub-agent split | Tool specialization per stage (script vs frames vs motion) | No verifier sub-agent — human approves final cut |
| Connectors | Drive, YouTube, Patreon, Telegram APIs | Distribution stack, not MCP issue trackers |
| Feedback signal | Views, RPM, client acceptance | Business metrics — not CI, lint, or test gates |
| State / memory | Organised Drive folders per episode | Asset library, not AGENTS.md |
What transfers to coding loops
- Scheduled heartbeat — the factory does not wait for you to open a chat; neither should triage or CI-repair loops.
- Stage-specialised tools — one brain trying to script, illustrate, animate, and score is the creative version of one agent grading its own code.
- Performance direction in prompts — Fokki writes ElevenLabs stage direction (pauses, volume drops), not raw dialogue paste; coding loops need equally explicit done conditions in
/goaltext. - Human gate on output — “approve the episode” maps to Triage inbox review and PR merge — optimise human time, do not remove judgment.
- Setup once, run indefinitely — the Make scenario is the media equivalent of wiring automations + skills once, then letting the loop compound.
Treat revenue figures in social factory posts as illustrative, not audited benchmarks. The architectural lesson is stable: factories — code or content — are designed loops with explicit stages, schedules, and gates. Coding loop engineering just demands harder oracles (tests, type checks, diffs) because “shipped” is easier to fake than “sounds convincing.”
Token economics and balance
| Pattern | Approximate token load | Mitigation |
|---|---|---|
| Single-agent medium coding loop | 50K–200K per run | Turn caps in /goal; cheaper model for explore/review |
| Fleet (orchestrator + 3 specialists) | 500K–2M+ per cycle | Batch only parallelisable work; stuck detection |
| Scheduled daily automation | Millions per week if always-on | Archive empty runs; scope skills tightly |
Sub-agents + /goal evaluator | Multiplicative per child session | Spend sub-agents on high-risk paths only |
Loops are not free — patterns diverge wildly if you are “token rich” vs “token poor.” Direct prompting still matters for ambiguity and architecture. Loops handle repetition; you handle judgement. The leverage point moved — it did not disappear.
Performance summary
| Dimension | Prompt era | Loop era |
|---|---|---|
| Your job | Write each turn | Design discover → plan → execute → verify → remember |
| Core cycle | Ask → answer | Five stages until verifiable done |
| Primitives | Context + prompt | 6 shared building blocks (both major tools) |
| Done signal | You decide to stop | /goal evaluator, Stop hook, or environmental oracles |
| Scale | One thread | Worktrees + sub-agents + orchestration layer |
| Feedback | Your eyes | Layered oracles — not self-critique alone |
| Knowledge | Re-explained each session | Skills + VISION.md / AGENTS.md compound |
| Risk profile | Slower, more oversight | Faster, higher verification + comprehension debt |
| Bottom line | — | Build the loop — stay the engineer who reviews what ships |
Research supplement
The following documentation pages from the official Claude Code docs provide additional technical depth beyond the article's reference links:
- Scheduled Tasks (
/loop): The Scheduled Tasks reference details how/loopworks alongside cloud Routines and Desktop scheduled tasks, including the full comparison table of scheduling options, jitter behaviour, seven-day expiry, and theloop.mdcustomisation mechanism. Notably, dynamic/loopschedules can use the Monitor tool internally to stream background process output, avoiding polling entirely. - Agent Loop Architecture: The Agent SDK: How the agent loop works page documents the full turn-and-message lifecycle, context window management, automatic compaction, and how
max_turns/maxBudgetUsdbounds apply. It also explains how subagents start with a fresh conversation context, which has direct implications for keeping loop context efficient over long runs.
Key technical detail not in the primary reference links: The /goal command is implemented as a session-scoped prompt-based Stop hook. This means developers who need evaluation logic beyond a short text condition (for example, running an actual script to verify state) can write a custom Stop hook instead — which gives them the same turn-by-turn evaluation model with full scripting power.
References
- Claude Code — /goal
- Claude Code /loop documentation
- Claude Code hooks
- Model Context Protocol (MCP)
- Claude Code: Run prompts on a schedule (/loop and scheduled tasks)
- Claude Code Agent SDK: How the agent loop works
- Claude Code: Automate actions with hooks (hooks guide)
- Codex automations
- Addy Osmani — Loop Engineering
- Agent Orchestrator
- Boris Cherny — loops not prompts
- Loops — what every AI engineer needs to know
- What are agent loops, really?
- AI animation factory — parallel scheduled pipeline
