wifi-densepose/vendor/ruvector/npm/packages/sona

@ruvector/sona

Self-Optimizing Neural Architecture (SONA) - Node.js bindings for adaptive learning with ReasoningBank.

SONA is a cutting-edge adaptive learning system that combines:

• Micro-LoRA (rank 1-2): Ultra-fast inference-time adaptation
• Base LoRA (rank 8+): Deeper background learning
• EWC++: Catastrophic forgetting prevention
• ReasoningBank: Pattern extraction and storage
• Dual Learning Loops: Instant (<1ms) and background (periodic) learning

Features

• 🚀 Instant Adaptation: Sub-millisecond learning updates during inference
• 🧠 Pattern Recognition: Automatic extraction and clustering of learned patterns
• 🔄 Dual Learning Loops: Balance speed and depth with instant and background learning
• 💾 Memory Preservation: EWC++ prevents catastrophic forgetting
• ⚡ High Performance: Native Rust implementation with SIMD optimizations
• 🎯 Production Ready: Used in large-scale LLM deployments

Installation

npm install @ruvector/sona

Quick Start

import { SonaEngine } from '@ruvector/sona';

// Create engine with hidden dimension
const engine = new SonaEngine(512);

// Or with custom configuration
const engine = SonaEngine.withConfig({
  hiddenDim: 512,
  microLoraRank: 2,
  baseLoraRank: 16,
  microLoraLr: 0.002,
  qualityThreshold: 0.7,
});

// Start a trajectory
const builder = engine.beginTrajectory(queryEmbedding);

// Record inference steps
builder.addStep(activations, attentionWeights, 0.8);
builder.addStep(activations2, attentionWeights2, 0.9);

// Complete trajectory
engine.endTrajectory(builder, 0.85); // quality score

// Apply learned transformations
const output = engine.applyMicroLora(input);

// Force learning cycle
const result = engine.forceLearn();
console.log(result);

// Find similar patterns
const patterns = engine.findPatterns(queryEmbedding, 5);
patterns.forEach(p => {
  console.log(`Pattern ${p.id}: quality=${p.avgQuality}, size=${p.clusterSize}`);
});

API Reference

SonaEngine

Main class for adaptive learning.

Constructor

new SonaEngine(hiddenDim: number)

Create a new SONA engine with default configuration.

Parameters:

• hiddenDim: Hidden dimension size (e.g., 256, 512, 1024)

Static Methods

SonaEngine.withConfig(config: SonaConfig): SonaEngine

Create engine with custom configuration.

Configuration Options:

interface SonaConfig {
  hiddenDim: number;              // Required: Hidden dimension
  embeddingDim?: number;          // Default: hiddenDim
  microLoraRank?: number;         // Default: 1 (range: 1-2)
  baseLoraRank?: number;          // Default: 8
  microLoraLr?: number;           // Default: 0.001
  baseLoraLr?: number;            // Default: 0.0001
  ewcLambda?: number;             // Default: 1000.0
  patternClusters?: number;       // Default: 50
  trajectoryCapacity?: number;    // Default: 10000
  backgroundIntervalMs?: number;  // Default: 3600000 (1 hour)
  qualityThreshold?: number;      // Default: 0.5
  enableSimd?: boolean;           // Default: true
}

Instance Methods

beginTrajectory(queryEmbedding: Float64Array | number[]): TrajectoryBuilder

Start recording a new inference trajectory.

endTrajectory(builder: TrajectoryBuilder, quality: number): void

Complete and submit trajectory for learning.

Parameters:

• builder: TrajectoryBuilder instance
• quality: Final quality score [0.0, 1.0]

applyMicroLora(input: Float64Array | number[]): Float64Array

Apply micro-LoRA transformation (instant learning).

applyBaseLora(layerIdx: number, input: Float64Array | number[]): Float64Array

Apply base-LoRA transformation to specific layer.

tick(): string | null

Run background learning cycle if due. Returns status message if executed.

forceLearn(): string

Force immediate background learning cycle.

flush(): void

Flush instant loop updates.

findPatterns(queryEmbedding: Float64Array | number[], k: number): LearnedPattern[]

Find k most similar learned patterns.

getStats(): string

Get engine statistics as JSON string.

setEnabled(enabled: boolean): void

Enable or disable learning.

isEnabled(): boolean

Check if engine is enabled.

TrajectoryBuilder

Builder for recording inference trajectories.

Methods

addStep(activations: Float64Array | number[], attentionWeights: Float64Array | number[], reward: number): void

Add a step to the trajectory.

Parameters:

• activations: Layer activations
• attentionWeights: Attention weights
• reward: Reward signal for this step

setRoute(route: string): void

Set model route identifier.

addContext(contextId: string): void

Add context ID to trajectory.

LearnedPattern

Represents a learned pattern from trajectory clustering.

interface LearnedPattern {
  id: string;
  centroid: Float64Array;
  clusterSize: number;
  totalWeight: number;
  avgQuality: number;
  createdAt: string;
  lastAccessed: string;
  accessCount: number;
  patternType: PatternType;
}

PatternType

Pattern classification enumeration.

enum PatternType {
  General = 'General',
  Reasoning = 'Reasoning',
  Factual = 'Factual',
  Creative = 'Creative',
  CodeGen = 'CodeGen',
  Conversational = 'Conversational',
}

Advanced Usage

LLM Integration Example

import { SonaEngine } from '@ruvector/sona';

class AdaptiveLLM {
  private sona: SonaEngine;

  constructor() {
    this.sona = SonaEngine.withConfig({
      hiddenDim: 4096,
      microLoraRank: 2,
      baseLoraRank: 16,
      microLoraLr: 0.002,
      qualityThreshold: 0.7,
      backgroundIntervalMs: 1800000, // 30 minutes
    });
  }

  async generate(prompt: string): Promise<string> {
    const embedding = await this.embed(prompt);
    const builder = this.sona.beginTrajectory(embedding);

    // Generate with SONA-enhanced layers
    const output = await this.runInference(builder);

    // Calculate quality score
    const quality = this.assessQuality(output);

    // Submit trajectory for learning
    this.sona.endTrajectory(builder, quality);

    // Periodic background learning
    const status = this.sona.tick();
    if (status) {
      console.log('Background learning:', status);
    }

    return output;
  }

  private async runInference(builder: TrajectoryBuilder): Promise<string> {
    let output = '';

    for (const layer of this.layers) {
      // Get layer activations
      const activations = layer.forward(/* ... */);
      const attention = layer.getAttention();

      // Apply micro-LoRA enhancement
      const enhanced = this.sona.applyMicroLora(activations);

      // Record step
      const reward = this.calculateReward(enhanced);
      builder.addStep(activations, attention, reward);

      // Continue generation with enhanced activations
      output += this.decode(enhanced);
    }

    return output;
  }
}

Pattern-Based Routing

// Find similar patterns for routing decisions
const patterns = engine.findPatterns(queryEmbedding, 3);

if (patterns.length > 0) {
  const topPattern = patterns[0];

  if (topPattern.patternType === 'CodeGen' && topPattern.avgQuality > 0.8) {
    // Route to specialized code generation model
    await routeToCodeModel(query);
  } else if (topPattern.patternType === 'Reasoning') {
    // Use chain-of-thought prompting
    await useCoTPrompting(query);
  }
}

Performance Monitoring

// Get statistics
const stats = JSON.parse(engine.getStats());
console.log(`
  Trajectories buffered: ${stats.trajectories_buffered}
  Patterns learned: ${stats.patterns_learned}
  Micro-LoRA updates: ${stats.micro_updates}
  Background cycles: ${stats.background_cycles}
`);

// Force learning when needed
if (stats.trajectories_buffered > 100) {
  const result = engine.forceLearn();
  console.log('Forced learning:', result);
}

Performance Characteristics

• Micro-LoRA Application: <1ms per forward pass
• Trajectory Recording: ~10μs per step
• Background Learning: Depends on buffer size (typically 100-500ms for 1000 trajectories)
• Pattern Search: O(k * n) where k = number of results, n = total patterns
• Memory Usage: ~50MB base + ~1KB per trajectory + ~10KB per pattern

Architecture

SONA implements a dual-loop learning architecture:

1. Instant Loop (<1ms):

   • Accumulates micro-LoRA gradients during inference
   • Updates on every trajectory
   • Rank-1 or rank-2 LoRA for minimal overhead

2. Background Loop (periodic):

   • Extracts patterns via k-means clustering
   • Updates base LoRA weights
   • Applies EWC++ for stability
   • Prunes low-quality patterns

Requirements

• Node.js >= 16
• Native bindings for your platform (automatically installed)

Supported Platforms

• Linux (x64, ARM64, ARM)
• macOS (x64, ARM64, Universal)
• Windows (x64, ARM64)
• FreeBSD (x64)

License

MIT OR Apache-2.0

Links

• GitHub Repository
• Documentation
• rUvector Project

Contributing

Contributions are welcome! Please see the main rUvector repository for contribution guidelines.

Acknowledgments

SONA is part of the rUvector project, building on research in:

• Low-Rank Adaptation (LoRA)
• Elastic Weight Consolidation (EWC)
• Continual Learning
• Neural Architecture Search

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Built with ❤️ by the rUv Team