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git-workflow

@elb-pr · 收录于 1 周前

Use when running claudikins-kernel:execute, decomposing plans into tasks, setting up two-stage review, deciding batch sizes, or handling stuck agents — enforces isolation, verification, and human checkpoints; prevents runaway parallelization and context death

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/ 下载安装
git-workflow.skill双击,或拖进 Claude 桌面版 / Cowork,即完成安装↓ .skill↓ .zip
用别的 agent?下载 .zip 解压,把文件夹放进它的技能目录
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Cursor自动读取上面两处目录
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/ 通过 npx 安装 校验哈希
npx oh-my-skill add elb-pr/claudikins-kernel/git-workflow
/ 通过 bash 安装
curl -fsSL https://oh-my-skill.com/install.sh | bash -s -- elb-pr/claudikins-kernel/git-workflow
/ 已经装过?验证本机副本,不用重装
npx oh-my-skill verify elb-pr/claudikins-kernel/git-workflow
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怎么用

技能原文 SKILL.md作者撰写 · MIT · 8b626a4

Git Workflow Methodology

When to use this skill

Use this skill when you need to:

  • Run the claudikins-kernel:execute command
  • Decompose plans into executable tasks
  • Set up two-stage code review
  • Decide batch sizes and checkpoints
  • Handle stuck agents or failed tasks
Core Philosophy
"I'd use 5-7 agents per SESSION, not 30 per batch." - Boris

Execution is about isolation, verification, and human checkpoints. Not speed.

The Six Principles
  1. One task = one branch - Isolation prevents pollution
  2. Fresh context per task - context: fork gives a clean slate
  3. Two-stage review - Spec compliance first, then code quality
  4. Human checkpoints between batches - Not between individual tasks
  5. Commands own git - Agents never checkout/merge/push
  6. Features are the unit - Batch at feature level, not task level
Batch Size Guidance (GOSPEL)

Wrong: 30 agents for 10 tasks (3 per task micro-management) Right: 5-7 agents total (feature-level batches)

| Scenario | Wrong | Right | | -------------------- | -------------------------- | ------------------ | | 10 tasks, 5 features | 30 micro-task agents | 5-7 feature agents | | Simple refactor | 10 agents for tiny changes | 1-2 feature agents |

Default --batch 1 is correct. Features are the unit of work.

Task Decomposition

From a plan, extract tasks that are:

| Quality | Definition | Example | | --------------- | ---------------------------------------------- | --------------------------------------------- | | Atomic | Completable in one agent session | "Add auth middleware" not "Build auth system" | | Testable | Has measurable acceptance criteria | "Returns 401 for invalid token" | | Independent | Minimal dependencies on other tasks | Can be reviewed in isolation | | Right-sized | Not too small (noise) or large (context death) | 50-200 lines of changes |

See [task-decomposition.md](references/task-decomposition.md) for patterns.

Review Stages

Two reviewers with different jobs. Never skip either.

Stage 1: Spec Compliance (spec-reviewer, opus)

Question: "Did it do what was asked?"

Checks:

  • All acceptance criteria addressed?
  • Any scope creep (features not in spec)?
  • Any missing requirements?

Output: PASS or FAIL with line references.

Stage 2: Code Quality (code-reviewer, opus)

Question: "Is it well-written?"

Checks:

  • Consistency with codebase style
  • Error handling
  • Edge cases
  • Naming clarity
  • Unnecessary complexity

Output: PASS or CONCERNS with confidence scores.

See [review-criteria.md](references/review-criteria.md) for detailed checklists.

Review Enforcement (MANDATORY)

This is non-negotiable. Violations here break the entire workflow.

The Iron Rule

After EVERY task completes, you MUST spawn BOTH reviewer agents:

  1. spec-reviewer - Spawned via Task(spec-reviewer, {...})
  2. code-reviewer - Spawned via Task(code-reviewer, {...}) (if spec passes)
What "MUST spawn" Means

| Allowed | NOT Allowed | |---------|-------------| | Task(spec-reviewer, { prompt: "...", context: "fork" }) | Inline spec check by orchestrator | | Task(code-reviewer, { prompt: "...", context: "fork" }) | "I'll just verify the code looks good" | | Waiting for agent output JSON | Making your own compliance table | | Reading from .claude/reviews/spec/ | Skipping because "it's a simple task" |

Inline Reviews Are VIOLATIONS

If you find yourself doing ANY of these, you are VIOLATING the methodology:

  • Creating a "Spec Compliance Check" table yourself
  • Writing "Verdict: PASS" without spawning an agent
  • Saying "Let me verify the implementation meets criteria"
  • Checking acceptance criteria in a loop instead of delegating

The orchestrator does NOT review. The orchestrator SPAWNS reviewers.

Pre-Merge Checklist (HARD GATE)

Before ANY merge decision can be offered to the user:

□ .claude/reviews/spec/{task_id}.json EXISTS for each task
□ .claude/reviews/code/{task_id}.json EXISTS for each task
□ Both files contain valid JSON with "verdict" field
□ spec-reviewer verdict is PASS (or user override documented)

If ANY file is missing: DO NOT proceed to merge. You skipped the review.

Why This Matters
  1. Consistency - Every task gets the same rigor, not "looks simple, I'll check it"
  2. Auditability - Review outputs are artifacts, not orchestrator judgments
  3. Separation of concerns - Orchestrator orchestrates, reviewers review
  4. No rationalization - You can't convince yourself your inline check is "good enough"
Verdict Matrix

What happens when reviewers return their verdicts:

| Spec Result | Code Result | Action | | ----------- | ----------- | ------------------------------------------------ | | PASS | PASS | Offer [Accept] [Revise anyway] | | PASS | CONCERNS | Offer [Accept with caveats] [Fix] [Klaus review] | | FAIL | \* | Always [Revise] or [Retry] |

See [review-conflict-matrix.md](references/review-conflict-matrix.md) for edge cases.

Batch Checkpoint Flow
All tasks in batch complete?
├── No → Wait for remaining
└── Yes →
    All reviews pass?
    ├── No →
    │   Retry count < 3?
    │   ├── Yes → Retry failed tasks
    │   └── No → Escalate to Klaus or human
    └── Yes →
        Present results to human
        └── Human decides: [Accept] [Revise] [Retry]

See [batch-patterns.md](references/batch-patterns.md) for decision trees.

Rationalizations to Resist

Agents under pressure find excuses. These are all violations:

| Excuse | Reality | | ------------------------------------------ | ------------------------------------------------------------------- | | "30 agents is fine, tasks are independent" | More agents = more chaos. 5-7 per session, features as units. | | "I'll just checkout main to compare" | Agents don't own git. Use git show main:file instead. | | "Skip spec review, code looks correct" | Spec review catches scope creep. Never skip. | | "I'll do the review myself, it's simple" | Spawn the reviewer agents. Inline reviews are VIOLATIONS. | | "Both passed, auto-merge is safe" | Human checkpoint required. Always. | | "Context is fine, I'll continue" | ACM at 60% = checkpoint offer. 75% = mandatory stop. | | "This tiny task doesn't need a branch" | One task = one branch. No exceptions. Isolation prevents pollution. | | "Retry limit is just a guideline" | 2 retries then escalate. Infinite retry = infinite waste. | | "I'll merge my changes when done" | Commands own merge. You own implementation. Stay in your lane. |

All of these mean: Follow the methodology. Speed is not the goal.

Red Flags — STOP and Reassess

If you're thinking any of these, you're about to violate the methodology:

  • "Let me just run git checkout..."
  • "30 tasks, 30 agents, maximum parallelism"
  • "Review passed, no need for human checkpoint"
  • "Context is getting tight but I can finish"
  • "This is simple, don't need isolation"
  • "I'll merge it myself"
  • "Retry limit doesn't apply here"
  • "Spec review is redundant if code review passes"
  • "Let me verify the implementation meets criteria" (SPAWN THE AGENT)
  • "I'll create a quick compliance table" (SPAWN THE AGENT)

All of these mean: STOP. Commands own git. Humans own checkpoints. Reviewers own reviews. You own orchestration.

Robustness Patterns

Things go wrong. Here's how to handle them.

SubagentStop Hook Failure (A-6)

If the capture hook fails, agent output is lost.

Pattern: Write to backup location first, then move to primary.

# Always backup first
echo "$OUTPUT" > "$BACKUP_DIR/agent-$(date +%s).json"
# Then move to primary
mv "$BACKUP_DIR/..." "$PRIMARY"
Malformed JSON Output (A-7)

Agents sometimes produce invalid JSON.

Pattern: Validate required fields before accepting.

REQUIRED='["task_id", "status"]'
jq -e "all($REQUIRED[]; has(.))" "$OUTPUT" || exit 2
Task Branch Directory Export (A-8)

Agents need to know where to work.

Pattern: Export directory as environment variable in SubagentStart hook.

export TASK_BRANCH_DIR="$PROJECT_DIR"
export TASK_BRANCH_NAME="execute/task-${TASK_ID}-${SLUG}"
Model Rate Limiting (A-10)

Opus gets rate limited more than Sonnet.

Pattern: Offer fallback options to human.

  1. Notify: "Opus rate limited. Options:"
  2. Offer: [Wait 60s] [Use Sonnet fallback] [Abort]
  3. If fallback, add caveat to review output
Context Exhaustion Mid-Task (A-11)

Agent runs out of context before finishing.

Pattern: Output partial state and mark as resumable.

{
  "status": "partial",
  "files_changed": ["completed work..."],
  "next_steps": ["what remains..."],
  "checkpoint_hash": "sha256:..."
}
Dependency Failure Chains (S-7)

Task Y depends on Task X. Task X fails. What happens to Y?

See [dependency-failure-chains.md](references/dependency-failure-chains.md).

Branch Collision (S-8)

Two tasks accidentally get the same branch name.

See [branch-collision-detection.md](references/branch-collision-detection.md).

Branch Guard Recovery (S-9)

The git-branch-guard hook blocks something it shouldn't.

See [branch-guard-recovery.md](references/branch-guard-recovery.md).

Batch Size Verification (S-10)

Validating batch sizes before execution starts.

See [batch-size-verification.md](references/batch-size-verification.md).

Task Branch Recovery (S-12)

Recovering orphaned branches from crashed sessions.

See [task-branch-recovery.md](references/task-branch-recovery.md).

Circuit Breakers (S-13)

Preventing cascading failures when operations fail repeatedly.

Pattern: Track failure rate. If threshold exceeded, "open" the circuit - fail fast without attempting.

Circuit: agent_spawn
State: OPEN (3 failures in 60s)
Reset in: 30 seconds

[Wait for reset] [Force close] [Skip operation]

See [circuit-breakers.md](references/circuit-breakers.md).

Execution Tracing (S-14)

Debugging execution graphs and understanding what happened.

Pattern: Record spans for each operation. Visualise as waterfall or dependency graph.

Trace: exec-session-xyz
├── batch_1 (45s)
│   ├── task-1 (20s) ✓
│   └── task-2 (25s) ✓
└── batch_2 (60s)
    └── task-3 (60s) ✓

Critical path: batch_1 → batch_2

See [execution-tracing.md](references/execution-tracing.md).

Stuck Detection

| Signal | Threshold | Response | | --------------------- | ----------------------------- | ------------------- | | Tool call flooding | 20 calls without file changes | Warning, then Klaus | | Time without progress | 10 minutes | Warning, then Klaus | | Repeated failures | Same error 3x | Pause, offer Klaus | | Context burn rate | ACM at 60% | Checkpoint offer | | Review timeout | 5 minutes per reviewer | Offer [Wait] [Skip] |

Anti-Patterns

Don't do these:

  • Running git checkout/merge/push from agents
  • Batching 30+ tasks in parallel
  • Skipping spec review because "code looks fine"
  • Auto-merging without human checkpoint
  • Ignoring stuck signals
  • Continuing after context warnings
References

Full documentation in this skill's references/ folder:

  • [task-decomposition.md](references/task-decomposition.md) - How to break down plans
  • [review-criteria.md](references/review-criteria.md) - What reviewers check (400 LOC threshold, attack surface tracing)
  • [batch-patterns.md](references/batch-patterns.md) - Checkpoint decision patterns (coordinated checkpoints, load shedding, deadline propagation)
  • [dependency-failure-chains.md](references/dependency-failure-chains.md) - When dependent tasks fail
  • [branch-collision-detection.md](references/branch-collision-detection.md) - Preventing duplicate branches
  • [branch-guard-recovery.md](references/branch-guard-recovery.md) - Recovering from guard failures
  • [batch-size-verification.md](references/batch-size-verification.md) - Validating batch sizes
  • [review-conflict-matrix.md](references/review-conflict-matrix.md) - Handling reviewer disagreements (RESOLVE framework)
  • [task-branch-recovery.md](references/task-branch-recovery.md) - Recovering orphaned branches
  • [circuit-breakers.md](references/circuit-breakers.md) - Preventing cascading failures (circuit breaker pattern, timeout strategies)
  • [execution-tracing.md](references/execution-tracing.md) - Debugging execution graphs (spans, traces, critical path analysis)
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