| name | migrating-rule-packs |
| description | Run a code migration (zod → typebox, fetch → http-request, lib → lib-stable, etc.) as a rule-pack-driven autonomous loop across many target files in parallel. Runs a Workflow that streams the target files through a transform → build/fix/check/test pipeline, one worktree-isolated agent per file, with a feedback channel that rewrites PR-review comments back into the rule files. Use when a migration touches 10+ files with a deterministic transformation, when each target file is independently transformable, or when human-led serial editing would dominate the wall-clock time. The skill packages the four pieces a rule-pack migration needs: a rule-pack format, an autonomous per-file build/fix/check/test loop, parallel worktree execution, and a feedback channel that rewrites PR-review comments back into the rule files. |
migrating-rule-packs
Codify the agentic-migration pattern Salesforce reported in their how engineering became agentic post: markdown rule files + a reference implementation + an autonomous build/fix/check/test loop + parallel worktree spawns + PR-review feedback rewritten back into the rules. The autonomous per-file loop runs as a Workflow — a pipeline() over the target files, one worktree-isolated agent per file streaming transform → build/fix/check/test. The wheelhouse already has the canonical-and-cascade shape this pattern depends on; this skill names the pattern so it stops being recreated ad-hoc per migration.
🚨 This skill is for mechanical migrations, not redesigns. If you don't have a deterministic transformation that runs the same way on every target file, you don't have a rule-pack migration — you have a refactor that wants human judgment per call site. Use the refactor-cleaner agent or hand-edit instead. Rule-packs assume "given input shape A, produce output shape B" with finite exception cases.
When to use
- Type-system migrations: zod → typebox, ajv → typebox, valibot → typebox.
- API migrations: bare
fetch() → @socketsecurity/lib-stable/http-request helpers, node:child_process → lib spawn, raw fs.rm → safeDelete.
- Import-path lifts:
@socketsecurity/lib → @socketsecurity/lib-stable (in scripts/** + .claude/hooks/**).
- Patch-format conversions: legacy
Socket Security: headers → # @<project>-versions: vX.Y.Z + # @description: ....
- Cross-fleet variant-analysis fixes: same shape found in N repos, fixed N times.
When NOT to use
- One-off design changes that need per-call-site human judgment.
- Migrations where the transformation depends on runtime behavior the rules can't statically detect.
- Single-file changes — the parallel worktree overhead isn't worth it under ~5 target files.
- Migrations whose target shape isn't stable yet (the rules are wet cement; pin them first via a reference implementation).
The four pieces
1. The rule pack
A rule pack is a directory of markdown files at:
<repo>/.claude/migrations/<migration-name>/rules/*.md
The directory is untracked by default — same as .claude/plans/. The rule pack is per-migration working memory, not a fleet artifact. Promote stable patterns to lint rules or hooks once the migration completes.
Each rule file is one transformation. Shape:
# Rule: <short name>
## Pattern (before)
\`\`\`ts
import { z } from 'zod'
const Schema = z.object({ name: z.string(), age: z.number().optional() })
\`\`\`
## Replacement (after)
\`\`\`ts
import { Type, type Static } from '@sinclair/typebox'
const Schema = Type.Object({ name: Type.String(), age: Type.Optional(Type.Number()) })
type Schema = Static<typeof Schema>
\`\`\`
## When the rule applies
- The file imports from `'zod'`.
- The schema is built via `z.object(...)` (not `z.union(...)` — that's a separate rule).
## When the rule does NOT apply
- The schema is consumed by a library that requires zod specifically (rare; cite the library when this triggers).
- The schema uses `.refine()` — typebox has no direct equivalent; the rule defers to a hand-edit.
## Reference implementation
PR #<N> in <repo> applied this rule to <path/to/file.ts>. The diff is the canonical example.
The skill author writes the rule pack first, lands a reference PR by hand, then unleashes the autonomous loop on remaining target files using the reference as ground truth.
2 + 3. The autonomous per-file loop: author a Workflow
The per-file loop is built as lib/run-migration.mts — a bounded-concurrency worker pool over the target files (each a fresh worktree off origin/<default-branch> on a migration/<name>-<slug> branch). The target files are independent units that each stream through the same transform → verify stages, and the per-file agents MUTATE files in parallel, so they run worktree-isolated. The intelligence is contained: the locked-down agent's ONLY job is "apply the rule pack to this one file"; everything else (survey, gate verdict, commit/push/PR) is deterministic code. This section is the architecture the runner implements:
- Resolve the target set first (plain code, no agents). Survey the target files (
rg the before-pattern across the migration scope), load the rule-pack markdown, resolve the default branch per CLAUDE.md's Default branch fallback recipe. Build the per-file work items.
phase('Migrate') — pipeline(targetFiles, transform, buildFixCheckTest). Each target file streams through two stages, both as agent() with isolation: 'worktree' (a fresh worktree off origin/<default-branch> on a migration/<migration-name>-<target-slug> branch, mirroring cascade's convention at <repo>/.claude/worktrees/<migration-name>/<target-slug>/):
transform — self-prompt with the rule-pack as context; apply the rules to the one target file, returning a TRANSFORM_SCHEMA ({ file, rulesApplied: string[], exceptions: [{ rule, why }] }).
buildFixCheckTest — the validation gate: loop pnpm run build && pnpm run check && pnpm run test up to 3 attempts; on failure append result.stderr to the agent's rule-context and retry; on success git add <file> + commit + push the branch + open the PR. Returns a RESULT_SCHEMA ({ file, status: landed|exception, attempts, prUrl?, failureMode? }). pipeline() gives per-item streaming — file N+1 starts its transform while file N is still in build/check/test — without a barrier across files.
- The
pipeline() runtime caps concurrency; default 5 in-flight worktree agents (higher risks lock-stepped pnpm/cargo runs hammering shared caches; lower under-utilizes). Tune per migration. If the migration accumulates (the rule-pack keeps growing as PRs land), make the pipeline budget-aware / loop-until-done: re-survey for newly-matching files after each rule-pack update and feed them back through.
- Barrier → report. Collect every item's
RESULT_SCHEMA, .filter(Boolean), and surface any status: exception files as per-file findings the human handles. Worktrees are cleaned up after the PR lands or by cleaning-ci's sibling cleanup hook.
Return { landed, exceptions, prUrls } from the script. The RESULT_SCHEMA replaces re-parsing each Agent's free-text exit — every file returns validated landed/exception status the report reads directly. The validation gate stays the same: if pnpm run check doesn't catch the regression, the rule needs a tighter assertion.
4. PR-review feedback as rule rewrites
Every merged PR's review comments get rewritten back into the rule files as a NEW commit on the rule-pack. This is the feedback loop that makes the rule pack improve over time — the human reviewer's diff suggestions become the next iteration's "When the rule does NOT apply" entries.
Workflow:
- Reviewer leaves an inline comment on a migration PR ("don't use Type.Number() for IDs — use Type.Integer() with constraints").
- Skill operator updates the relevant rule file with the new exception.
- Remaining open migration PRs receive the rule-pack update via
git pull in their worktrees; they re-run the loop from scratch.
The rule pack is wet cement until the migration completes; the last PR's rules are the final form. After the migration lands, the operator may promote the stable rules to an oxlint rule or a .claude/hooks/ guard (per CLAUDE.md Compound lessons).
How to invoke
The operational runner is lib/run-migration.mts — it owns the deterministic machinery (survey, worktree-per-file, the locked-down per-file transform, the build/fix/check/test gate, the per-file commit/push/PR, the report). The two pieces that need a human stay with you: writing the rule pack + reference PR (genuine judgment), and reviewing each PR + folding inline comments back into the rules (the feedback loop).
Per-migration flow:
-
Author rules + reference PR (you). Write <repo>/.claude/migrations/<name>/rules/*.md (one transformation per file, shape in §1). Hand-port one file, land it, cite its SHA in every rule. The runner reads whatever *.md lives in --rules, so the rules ARE the ground truth.
-
Run the loop:
node .claude/skills/fleet/migrating-rule-packs/lib/run-migration.mts \
--name zod-to-typebox \
--rules .claude/migrations/zod-to-typebox/rules \
--survey 'z\.(object|union|literal|enum|tuple|array)' \
--scope packages \
--repo SocketDev/socket-mcp
It surveys the target set, then for each file spawns a worktree-isolated, locked-down agent (spawnAiAgent + AI_PROFILE.verify — four-flag lockdown, permissionMode: acceptEdits, never the raw claude CLI) that applies the rule pack and self-runs the gate; the runner re-asserts build → check → test in plain code (the agent's self-report is a lead, not the verdict), then deterministically commits + pushes + opens the PR. --dry-run runs the transform + gate but never lands. --concurrency (default 5), --attempts (default 3), --model, --effort tune the run. Exits non-zero while any file is in exception status.
-
Review + fold feedback (you). Review each PR, merge the clean ones. Inline review comments become new "When the rule does NOT apply" entries in the rule files (the §4 loop); re-run the runner to pick up newly-matching files against the updated rules.
Acceptance for the skill itself
- This SKILL.md exists ✓ (you're reading it).
- The operational runner
lib/run-migration.mts is built ✓ and the SKILL thin-wraps it.
- The first real migration runs through it end-to-end; record the actual speedup vs. estimated serial time wherever the operator tracks it.
Precedent
The cascade orchestrator (template/.claude/skills/fleet/cascading-fleet/lib/cascade-template.mts) already does parallel-worktree execution across the fleet. Pattern is "lift cascade's runtime for migrations" — same worktree convention, same per-target commit shape, different inner loop.
Related fleet skills:
cascading-fleet — propagate one wheelhouse SHA to every fleet repo (this skill's parent pattern).
refactor-cleaner (agent) — for non-mechanical refactors that need per-call-site human judgment.
looping-quality — for in-repo cleanup waves; rule-pack migrations are the cross-repo / cross-file generalization.
What NOT to do
- Don't invoke this skill without a reference PR landed first. The reference PR is ground truth; without it, the autonomous loop has nothing to validate against.
- Don't parallel-cap above 5 by default. Lock-stepped pnpm/cargo runs hammer shared caches.
- Don't mark a migration done if any target file landed in "exception (human handles)" status — those are the rule-pack's tells about coverage gaps. Either land the exception by hand (and update the rules), or accept the migration as partial.
- Don't delete the per-repo rule pack after the migration lands — promote the stable patterns to an oxlint rule or hook, but leave the
.claude/migrations/<name>/ directory as historical context for the next analogous migration.