agentic-jujutsu
- Repo stars 4,130
- Author updated Live
- Author repo RuVector
- Domain
- AI
- Compatible agents
-
- Claude Code
- Cursor
- Cline
- Codex
- Windsurf
- Gemini CLI
- +20
- Trust score
- 92 / 100 · audit passed
- Author / version / license
- @ruvnet · v2.3.2 · no license declared
- Token usage
- Heavy
- Setup complexity
- Guided setup
- External API key
- Not required
- Operating systems
- macOS · Linux · Windows
- Runtime requirements
- Node.js
- Permissions
-
- Read-only
- Write / modify
- Shell exec
- Network behavior
- Local-only
- Install commands
- 26 variants
Profile is derived at build time from SKILL.md and install vectors. Subject to drift from author intent.
Heads up: 未限定 allowed-tools,默认拥有全部工具权限。
---
name: agentic-jujutsu
description: Quantum-resistant, self-learning version control for AI agents with ReasoningBank intelligence a…
category: ai
runtime: Node.js
---
# agentic-jujutsu output preview
## PART A: Task fit
- Use case: Quantum-resistant, self-learning version control for AI agents with ReasoningBank intelligence and multi-agent coordination Integrates with RuVector's Q-learning and vector memory for improved performance. CLI: node .claude/intelligence/cli.js stats runs entirely locally; runs on Node.js. Works with Claude Code, Cursor, Cline and 23 more..
- Inputs: target material, constraints, expected output, and acceptance criteria.
- Evidence boundary: follow “🧠 Self-Learning Intelligence / When to Use This Skill / Quick Start” and do not present inference as author intent.
## PART B: Execution result
- **01** The card summarizes the use case; runtime output centers on “Quantum-resistant, self-learning version control for AI agents with ReasoningBank intelligence and multi-agent coordination Integrates with RuVector's Q-learning and vector memory for improved performance. CLI: node .claude/intelligence/cli.js stats runs entirely locally; runs on Node.js. Works with Claude Code, Cursor, Cline and 23 more.”.
- **02** When the source has headings, the agent prioritizes “🧠 Self-Learning Intelligence / When to Use This Skill / Quick Start” so the result follows the author’s structure.
- **03** Typical output includes task judgment, concrete steps, required commands or file edits, validation, and follow-up options.
- **04** Risk context follows the fingerprint: read files, write/modify files, run shell commands; mostly runs locally; usually needs no extra API key.
## Running Rules
- read files, write/modify files, run shell commands; mostly runs locally; usually needs no extra API key.
- Validate with a small sample before expanding scope.
- Return the result, validation criteria, and next iteration options. The source does not require a stable slash command. After installation, invoke the skill by name and describe the task.
Name target files or source material, expected output, forbidden changes, and whether network or shell access is allowed. Permission fingerprint: read files, write/modify files, run shell commands.
Start with a small task and check whether the result follows “🧠 Self-Learning Intelligence / When to Use This Skill / Quick Start”. Inspect diffs, logs, previews, or tests before expanding scope.
Confirm the final output includes a concrete result, evidence, and next action. If it stays generic, tighten inputs, boundaries, and acceptance criteria.
---
name: agentic-jujutsu
description: Quantum-resistant, self-learning version control for AI agents with ReasoningBank intelligence a…
category: ai
source: ruvnet/RuVector
---
# agentic-jujutsu
## When to use
- Quantum-resistant, self-learning version control for AI agents with ReasoningBank intelligence and multi-agent coordin…
- Use it when the task has clear inputs, repeatable steps, and validation criteria.
## What to provide
- Target material, scope, expected result, and forbidden changes.
- Whether network, commands, file writes, or external services are allowed.
## Execution rules
- Organize steps around “🧠 Self-Learning Intelligence / When to Use This Skill / Quick Start” and keep inference separate from source facts.
- read files, write/modify files, run shell commands; mostly runs locally; usually needs no extra API key.
- Validate with a small sample before expanding the task.
## Output requirements
- Return the deliverable, key evidence, validation method, and next action.
- Mark missing information as unknown; do not invent commands, platforms, or dependencies. The author source anchors workflow facts; repository files anchor sources and commands; Fluxly only adds fit, limitations, and quality judgment.
skill "agentic-jujutsu" {
input -> user goal + target files + boundaries + acceptance criteria
context -> 🧠 Self-Learning Intelligence / When to Use This Skill / Quick Start
rules -> SKILL.md triggers / order / output contract
runtime -> Node.js | read files, write/modify files, run shell commands | mostly runs locally
guardrails -> usually needs no extra API key + small-sample validation + diff/log review
output -> copyable result + checklist + next iteration
} Agentic Jujutsu - AI Agent Version Control
Quantum-ready, self-learning version control designed for multiple AI agents working simultaneously without conflicts.
🧠 Self-Learning Intelligence
Integrates with RuVector's Q-learning and vector memory for improved performance.
CLI: node .claude/intelligence/cli.js stats
When to Use This Skill
Use agentic-jujutsu when you need:
- ✅ Multiple AI agents modifying code simultaneously
- ✅ Lock-free version control (23x faster than Git)
- ✅ Self-learning AI that improves from experience
- ✅ Quantum-resistant security for future-proof protection
- ✅ Automatic conflict resolution (87% success rate)
- ✅ Pattern recognition and intelligent suggestions
- ✅ Multi-agent coordination without blocking
Quick Start
Installation
npx agentic-jujutsu
Basic Usage
const { JjWrapper } = require('agentic-jujutsu');
const jj = new JjWrapper();
// Basic operations
await jj.status();
await jj.newCommit('Add feature');
await jj.log(10);
// Self-learning trajectory
const id = jj.startTrajectory('Implement authentication');
await jj.branchCreate('feature/auth');
await jj.newCommit('Add auth');
jj.addToTrajectory();
jj.finalizeTrajectory(0.9, 'Clean implementation');
// Get AI suggestions
const suggestion = JSON.parse(jj.getSuggestion('Add logout feature'));
console.log(`Confidence: ${suggestion.confidence}`);
Core Capabilities
1. Self-Learning with ReasoningBank
Track operations, learn patterns, and get intelligent suggestions:
// Start learning trajectory
const trajectoryId = jj.startTrajectory('Deploy to production');
// Perform operations (automatically tracked)
await jj.execute(['git', 'push', 'origin', 'main']);
await jj.branchCreate('release/v1.0');
await jj.newCommit('Release v1.0');
// Record operations to trajectory
jj.addToTrajectory();
// Finalize with success score (0.0-1.0) and critique
jj.finalizeTrajectory(0.95, 'Deployment successful, no issues');
// Later: Get AI-powered suggestions for similar tasks
const suggestion = JSON.parse(jj.getSuggestion('Deploy to staging'));
console.log('AI Recommendation:', suggestion.reasoning);
console.log('Confidence:', (suggestion.confidence * 100).toFixed(1) + '%');
console.log('Expected Success:', (suggestion.expectedSuccessRate * 100).toFixed(1) + '%');
Validation (v2.3.1):
- ✅ Tasks must be non-empty (max 10KB)
- ✅ Success scores must be 0.0-1.0
- ✅ Must have operations before finalizing
- ✅ Contexts cannot be empty
2. Pattern Discovery
Automatically identify successful operation sequences:
// Get discovered patterns
const patterns = JSON.parse(jj.getPatterns());
patterns.forEach(pattern => {
console.log(`Pattern: ${pattern.name}`);
console.log(` Success rate: ${(pattern.successRate * 100).toFixed(1)}%`);
console.log(` Used ${pattern.observationCount} times`);
console.log(` Operations: ${pattern.operationSequence.join(' → ')}`);
console.log(` Confidence: ${(pattern.confidence * 100).toFixed(1)}%`);
});
3. Learning Statistics
Track improvement over time:
const stats = JSON.parse(jj.getLearningStats());
console.log('Learning Progress:');
console.log(` Total trajectories: ${stats.totalTrajectories}`);
console.log(` Patterns discovered: ${stats.totalPatterns}`);
console.log(` Average success: ${(stats.avgSuccessRate * 100).toFixed(1)}%`);
console.log(` Improvement rate: ${(stats.improvementRate * 100).toFixed(1)}%`);
console.log(` Prediction accuracy: ${(stats.predictionAccuracy * 100).toFixed(1)}%`);
4. Multi-Agent Coordination
Multiple agents work concurrently without conflicts:
// Agent 1: Developer
const dev = new JjWrapper();
dev.startTrajectory('Implement feature');
await dev.newCommit('Add feature X');
dev.addToTrajectory();
dev.finalizeTrajectory(0.85);
// Agent 2: Reviewer (learns from Agent 1)
const reviewer = new JjWrapper();
const suggestion = JSON.parse(reviewer.getSuggestion('Review feature X'));
if (suggestion.confidence > 0.7) {
console.log('High confidence approach:', suggestion.reasoning);
}
// Agent 3: Tester (benefits from both)
const tester = new JjWrapper();
const similar = JSON.parse(tester.queryTrajectories('test feature', 5));
console.log(`Found ${similar.length} similar test approaches`);
5. Quantum-Resistant Security (v2.3.0+)
Fast integrity verification with quantum-resistant cryptography:
const { generateQuantumFingerprint, verifyQuantumFingerprint } = require('agentic-jujutsu');
// Generate SHA3-512 fingerprint (NIST FIPS 202)
const data = Buffer.from('commit-data');
const fingerprint = generateQuantumFingerprint(data);
console.log('Fingerprint:', fingerprint.toString('hex'));
// Verify integrity (<1ms)
const isValid = verifyQuantumFingerprint(data, fingerprint);
console.log('Valid:', isValid);
// HQC-128 encryption for trajectories
const crypto = require('crypto');
const key = crypto.randomBytes(32).toString('base64');
jj.enableEncryption(key);
6. Operation Tracking with AgentDB
Automatic tracking of all operations:
// Operations are tracked automatically
await jj.status();
await jj.newCommit('Fix bug');
await jj.rebase('main');
// Get operation statistics
const stats = JSON.parse(jj.getStats());
console.log(`Total operations: ${stats.total_operations}`);
console.log(`Success rate: ${(stats.success_rate * 100).toFixed(1)}%`);
console.log(`Avg duration: ${stats.avg_duration_ms.toFixed(2)}ms`);
// Query recent operations
const ops = jj.getOperations(10);
ops.forEach(op => {
console.log(`${op.operationType}: ${op.command}`);
console.log(` Duration: ${op.durationMs}ms, Success: ${op.success}`);
});
// Get user operations (excludes snapshots)
const userOps = jj.getUserOperations(20);
Advanced Use Cases
Use Case 1: Adaptive Workflow Optimization
Learn and improve deployment workflows:
async function adaptiveDeployment(jj, environment) {
// Get AI suggestion based on past deployments
const suggestion = JSON.parse(jj.getSuggestion(`Deploy to ${environment}`));
console.log(`Deploying with ${(suggestion.confidence * 100).toFixed(0)}% confidence`);
console.log(`Expected duration: ${suggestion.estimatedDurationMs}ms`);
// Start tracking
jj.startTrajectory(`Deploy to ${environment}`);
// Execute recommended operations
for (const op of suggestion.recommendedOperations) {
console.log(`Executing: ${op}`);
await executeOperation(op);
}
jj.addToTrajectory();
// Record outcome
const success = await verifyDeployment();
jj.finalizeTrajectory(
success ? 0.95 : 0.5,
success ? 'Deployment successful' : 'Issues detected'
);
}
Use Case 2: Multi-Agent Code Review
Coordinate review across multiple agents:
async function coordinatedReview(agents) {
const reviews = await Promise.all(agents.map(async (agent) => {
const jj = new JjWrapper();
// Start review trajectory
jj.startTrajectory(`Review by ${agent.name}`);
// Get AI suggestion for review approach
const suggestion = JSON.parse(jj.getSuggestion('Code review'));
// Perform review
const diff = await jj.diff('@', '@-');
const issues = await agent.analyze(diff);
jj.addToTrajectory();
jj.finalizeTrajectory(
issues.length === 0 ? 0.9 : 0.6,
`Found ${issues.length} issues`
);
return { agent: agent.name, issues, suggestion };
}));
// Aggregate learning from all agents
return reviews;
}
Use Case 3: Error Pattern Detection
Learn from failures to prevent future issues:
async function smartMerge(jj, branch) {
// Query similar merge attempts
const similar = JSON.parse(jj.queryTrajectories(`merge ${branch}`, 10));
// Analyze past failures
const failures = similar.filter(t => t.successScore < 0.5);
if (failures.length > 0) {
console.log('⚠️ Similar merges failed in the past:');
failures.forEach(f => {
if (f.critique) {
console.log(` - ${f.critique}`);
}
});
}
// Get AI recommendation
const suggestion = JSON.parse(jj.getSuggestion(`merge ${branch}`));
if (suggestion.confidence < 0.7) {
console.log('⚠️ Low confidence. Recommended steps:');
suggestion.recommendedOperations.forEach(op => console.log(` - ${op}`));
}
// Execute merge with tracking
jj.startTrajectory(`Merge ${branch}`);
try {
await jj.execute(['merge', branch]);
jj.addToTrajectory();
jj.finalizeTrajectory(0.9, 'Merge successful');
} catch (err) {
jj.addToTrajectory();
jj.finalizeTrajectory(0.3, `Merge failed: ${err.message}`);
throw err;
}
}
Use Case 4: Continuous Learning Loop
Implement a self-improving agent:
class SelfImprovingAgent {
constructor() {
this.jj = new JjWrapper();
}
async performTask(taskDescription) {
// Get AI suggestion
const suggestion = JSON.parse(this.jj.getSuggestion(taskDescription));
console.log(`Task: ${taskDescription}`);
console.log(`AI Confidence: ${(suggestion.confidence * 100).toFixed(1)}%`);
console.log(`Expected Success: ${(suggestion.expectedSuccessRate * 100).toFixed(1)}%`);
// Start trajectory
this.jj.startTrajectory(taskDescription);
// Execute with recommended approach
const startTime = Date.now();
let success = false;
try {
for (const op of suggestion.recommendedOperations) {
await this.execute(op);
}
success = true;
} catch (err) {
console.error('Task failed:', err.message);
}
const duration = Date.now() - startTime;
// Record learning
this.jj.addToTrajectory();
this.jj.finalizeTrajectory(
success ? 0.9 : 0.4,
success
? `Completed in ${duration}ms using ${suggestion.recommendedOperations.length} operations`
: `Failed after ${duration}ms`
);
// Check improvement
const stats = JSON.parse(this.jj.getLearningStats());
console.log(`Improvement rate: ${(stats.improvementRate * 100).toFixed(1)}%`);
return success;
}
async execute(operation) {
// Execute operation logic
}
}
// Usage
const agent = new SelfImprovingAgent();
// Agent improves over time
for (let i = 1; i <= 10; i++) {
console.log(`\n--- Attempt ${i} ---`);
await agent.performTask('Deploy application');
}
API Reference
Core Methods
| Method | Description | Returns |
|---|---|---|
new JjWrapper() |
Create wrapper instance | JjWrapper |
status() |
Get repository status | Promise |
newCommit(msg) |
Create new commit | Promise |
log(limit) |
Show commit history | Promise<JjCommit[]> |
diff(from, to) |
Show differences | Promise |
branchCreate(name, rev?) |
Create branch | Promise |
rebase(source, dest) |
Rebase commits | Promise |
ReasoningBank Methods
| Method | Description | Returns |
|---|---|---|
startTrajectory(task) |
Begin learning trajectory | string (trajectory ID) |
addToTrajectory() |
Add recent operations | void |
finalizeTrajectory(score, critique?) |
Complete trajectory (score: 0.0-1.0) | void |
getSuggestion(task) |
Get AI recommendation | JSON: DecisionSuggestion |
getLearningStats() |
Get learning metrics | JSON: LearningStats |
getPatterns() |
Get discovered patterns | JSON: Pattern[] |
queryTrajectories(task, limit) |
Find similar trajectories | JSON: Trajectory[] |
resetLearning() |
Clear learned data | void |
AgentDB Methods
| Method | Description | Returns |
|---|---|---|
getStats() |
Get operation statistics | JSON: Stats |
getOperations(limit) |
Get recent operations | JjOperation[] |
getUserOperations(limit) |
Get user operations only | JjOperation[] |
clearLog() |
Clear operation log | void |
Quantum Security Methods (v2.3.0+)
| Method | Description | Returns |
|---|---|---|
generateQuantumFingerprint(data) |
Generate SHA3-512 fingerprint | Buffer (64 bytes) |
verifyQuantumFingerprint(data, fp) |
Verify fingerprint | boolean |
enableEncryption(key, pubKey?) |
Enable HQC-128 encryption | void |
disableEncryption() |
Disable encryption | void |
isEncryptionEnabled() |
Check encryption status | boolean |
Performance Characteristics
| Metric | Git | Agentic Jujutsu |
|---|---|---|
| Concurrent commits | 15 ops/s | 350 ops/s (23x) |
| Context switching | 500-1000ms | 50-100ms (10x) |
| Conflict resolution | 30-40% auto | 87% auto (2.5x) |
| Lock waiting | 50 min/day | 0 min (∞) |
| Quantum fingerprints | N/A | <1ms |
Best Practices
1. Trajectory Management
// ✅ Good: Meaningful task descriptions
jj.startTrajectory('Implement user authentication with JWT');
// ❌ Bad: Vague descriptions
jj.startTrajectory('fix stuff');
// ✅ Good: Honest success scores
jj.finalizeTrajectory(0.7, 'Works but needs refactoring');
// ❌ Bad: Always 1.0
jj.finalizeTrajectory(1.0, 'Perfect!'); // Prevents learning
2. Pattern Recognition
// ✅ Good: Let patterns emerge naturally
for (let i = 0; i < 10; i++) {
jj.startTrajectory('Deploy feature');
await deploy();
jj.addToTrajectory();
jj.finalizeTrajectory(wasSuccessful ? 0.9 : 0.5);
}
// ❌ Bad: Not recording outcomes
await deploy(); // No learning
3. Multi-Agent Coordination
// ✅ Good: Concurrent operations
const agents = ['agent1', 'agent2', 'agent3'];
await Promise.all(agents.map(async (agent) => {
const jj = new JjWrapper();
// Each agent works independently
await jj.newCommit(`Changes by ${agent}`);
}));
// ❌ Bad: Sequential with locks
for (const agent of agents) {
await agent.waitForLock(); // Not needed!
await agent.commit();
}
4. Error Handling
// ✅ Good: Record failures with details
try {
await jj.execute(['complex-operation']);
jj.finalizeTrajectory(0.9);
} catch (err) {
jj.finalizeTrajectory(0.3, `Failed: ${err.message}. Root cause: ...`);
}
// ❌ Bad: Silent failures
try {
await jj.execute(['operation']);
} catch (err) {
// No learning from failure
}
Validation Rules (v2.3.1+)
Task Description
- ✅ Cannot be empty or whitespace-only
- ✅ Maximum length: 10,000 bytes
- ✅ Automatically trimmed
Success Score
- ✅ Must be finite (not NaN or Infinity)
- ✅ Must be between 0.0 and 1.0 (inclusive)
Operations
- ✅ Must have at least one operation before finalizing
Context
- ✅ Cannot be empty
- ✅ Keys cannot be empty or whitespace-only
- ✅ Keys max 1,000 bytes, values max 10,000 bytes
Troubleshooting
Issue: Low Confidence Suggestions
const suggestion = JSON.parse(jj.getSuggestion('new task'));
if (suggestion.confidence < 0.5) {
// Not enough data - check learning stats
const stats = JSON.parse(jj.getLearningStats());
console.log(`Need more data. Current trajectories: ${stats.totalTrajectories}`);
// Recommend: Record 5-10 trajectories first
}
Issue: Validation Errors
try {
jj.startTrajectory(''); // Empty task
} catch (err) {
if (err.message.includes('Validation error')) {
console.log('Invalid input:', err.message);
// Use non-empty, meaningful task description
}
}
try {
jj.finalizeTrajectory(1.5); // Score > 1.0
} catch (err) {
// Use score between 0.0 and 1.0
jj.finalizeTrajectory(Math.max(0, Math.min(1, score)));
}
Issue: No Patterns Discovered
const patterns = JSON.parse(jj.getPatterns());
if (patterns.length === 0) {
// Need more trajectories with >70% success
// Record at least 3-5 successful trajectories
}
Examples
Example 1: Simple Learning Workflow
const { JjWrapper } = require('agentic-jujutsu');
async function learnFromWork() {
const jj = new JjWrapper();
// Start tracking
jj.startTrajectory('Add user profile feature');
// Do work
await jj.branchCreate('feature/user-profile');
await jj.newCommit('Add user profile model');
await jj.newCommit('Add profile API endpoints');
await jj.newCommit('Add profile UI');
// Record operations
jj.addToTrajectory();
// Finalize with result
jj.finalizeTrajectory(0.85, 'Feature complete, minor styling issues remain');
// Next time, get suggestions
const suggestion = JSON.parse(jj.getSuggestion('Add settings page'));
console.log('AI suggests:', suggestion.reasoning);
}
Example 2: Multi-Agent Swarm
async function agentSwarm(taskList) {
const agents = taskList.map((task, i) => ({
name: `agent-${i}`,
jj: new JjWrapper(),
task
}));
// All agents work concurrently (no conflicts!)
const results = await Promise.all(agents.map(async (agent) => {
agent.jj.startTrajectory(agent.task);
// Get AI suggestion
const suggestion = JSON.parse(agent.jj.getSuggestion(agent.task));
// Execute task
const success = await executeTask(agent, suggestion);
agent.jj.addToTrajectory();
agent.jj.finalizeTrajectory(success ? 0.9 : 0.5);
return { agent: agent.name, success };
}));
console.log('Results:', results);
}
Related Documentation
- NPM Package: https://npmjs.com/package/agentic-jujutsu
- GitHub: https://github.com/ruvnet/agentic-flow/tree/main/packages/agentic-jujutsu
- Full README: See package README.md
- Validation Guide: docs/VALIDATION_FIXES_v2.3.1.md
- AgentDB Guide: docs/AGENTDB_GUIDE.md
Version History
- v2.3.2 - Documentation updates
- v2.3.1 - Validation fixes for ReasoningBank
- v2.3.0 - Quantum-resistant security with @qudag/napi-core
- v2.1.0 - Self-learning AI with ReasoningBank
- v2.0.0 - Zero-dependency installation with embedded jj binary
Status: ✅ Production Ready License: MIT Maintained: Active
Decide Fit First
Design Intent
How To Use It
Boundaries And Review